//***************************************************************************** // // am_hal_uart.h //! @file //! //! @brief Functions for accessing and configuring the UART. //! //! @addtogroup uart3p UART //! @ingroup apollo3phal //! @{ // //***************************************************************************** //***************************************************************************** // // Copyright (c) 2020, Ambiq Micro // 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 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 the copyright holder nor the names of its // contributors may be used to endorse or promote products derived from this // software without specific prior written permission. // // Third party software included in this distribution is subject to the // additional license terms as defined in the /docs/licenses directory. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" // AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE // IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE // ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER 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. // // This is part of revision 2.4.2 of the AmbiqSuite Development Package. // //***************************************************************************** #ifndef AM_HAL_UART_H #define AM_HAL_UART_H #ifdef __cplusplus extern "C" { #endif //***************************************************************************** // // CMSIS-style macro for handling a variable MSPI module number. // #define UARTn(n) ((UART0_Type*)(UART0_BASE + (n * (UART1_BASE - UART0_BASE)))) //***************************************************************************** //***************************************************************************** // // UART configuration options. // //***************************************************************************** typedef struct { // // Standard UART options. // uint32_t ui32BaudRate; uint32_t ui32DataBits; uint32_t ui32Parity; uint32_t ui32StopBits; uint32_t ui32FlowControl; // // Additional options. // uint32_t ui32FifoLevels; // // Buffers // uint8_t *pui8TxBuffer; uint32_t ui32TxBufferSize; uint8_t *pui8RxBuffer; uint32_t ui32RxBufferSize; } am_hal_uart_config_t; //***************************************************************************** // // @brief UART transfer structure. // // This structure describes a UART transaction that can be performed by \e // am_hal_uart_transfer() // //***************************************************************************** typedef struct { //! Determines whether data should be read or written. //! //! Should be either AM_HAL_UART_WRITE or AM_HAL_UART_READ uint32_t ui32Direction; //! Pointer to data to be sent, or space to fill with received data. uint8_t *pui8Data; //! Number of bytes to send or receive. uint32_t ui32NumBytes; //! Timeout in milliseconds. //! //! Given a timeout value, the \e am_hal_uart_transfer() function will keep //! trying to transfer data until either the number of bytes is satisfied, //! or the time runs out. If provided with a value of zero, the transfer //! function will only send as much data as it can immediately deal with. //! If provided with a timeout value of \e AM_HAL_UART_WAIT_FOREVER, the //! function will block until either the final "read" byte is received or //! the final "write" byte is placed in the output buffer. uint32_t ui32TimeoutMs; //! Number of bytes successfully transferred. uint32_t *pui32BytesTransferred; } am_hal_uart_transfer_t; //***************************************************************************** // // Maximum baudrate supported is 921600 for Apollo3-A1 and 1.5Mbaud for // Apollo3-B0. // //***************************************************************************** #define AM_HAL_UART_MAXIMUM_BAUDRATE 921600 //***************************************************************************** // // Uart transfer options. // //***************************************************************************** #define AM_HAL_UART_WRITE 0 #define AM_HAL_UART_READ 1 #define AM_HAL_UART_WAIT_FOREVER 0xFFFFFFFF //***************************************************************************** // // UART conficuration option values. // //***************************************************************************** // Data bits. #define AM_HAL_UART_DATA_BITS_8 (_VAL2FLD(UART0_LCRH_WLEN, 3)) #define AM_HAL_UART_DATA_BITS_7 (_VAL2FLD(UART0_LCRH_WLEN, 2)) #define AM_HAL_UART_DATA_BITS_6 (_VAL2FLD(UART0_LCRH_WLEN, 1)) #define AM_HAL_UART_DATA_BITS_5 (_VAL2FLD(UART0_LCRH_WLEN, 0)) // Parity. #define AM_HAL_UART_PARITY_NONE 0 #define AM_HAL_UART_PARITY_ODD UART0_LCRH_PEN_Msk #define AM_HAL_UART_PARITY_EVEN (UART0_LCRH_PEN_Msk | \ UART0_LCRH_EPS_Msk) // Stop Bits #define AM_HAL_UART_ONE_STOP_BIT (_VAL2FLD(UART0_LCRH_STP2, 0)) #define AM_HAL_UART_TWO_STOP_BITS (_VAL2FLD(UART0_LCRH_STP2, 1)) // Flow control #define AM_HAL_UART_FLOW_CTRL_NONE 0 #define AM_HAL_UART_FLOW_CTRL_CTS_ONLY UART_CR_CTSEN_Msk #define AM_HAL_UART_FLOW_CTRL_RTS_ONLY UART_CR_RTSEN_Msk #define AM_HAL_UART_FLOW_CTRL_RTS_CTS (UART0_CR_CTSEN_Msk | \ UART0_CR_RTSEN_Msk) // FIFO enable/disable. #define AM_HAL_UART_FIFO_ENABLE (_VAL2FLD(UART0_LCRH_FEN, 1)) #define AM_HAL_UART_FIFO_DISABLE (_VAL2FLD(UART0_LCRH_FEN, 0)) // TX FIFO interrupt level settings. #define AM_HAL_UART_TX_FIFO_1_8 (_VAL2FLD(UART0_IFLS_TXIFLSEL, 0)) #define AM_HAL_UART_TX_FIFO_1_4 (_VAL2FLD(UART0_IFLS_TXIFLSEL, 1)) #define AM_HAL_UART_TX_FIFO_1_2 (_VAL2FLD(UART0_IFLS_TXIFLSEL, 2)) #define AM_HAL_UART_TX_FIFO_3_4 (_VAL2FLD(UART0_IFLS_TXIFLSEL, 3)) #define AM_HAL_UART_TX_FIFO_7_8 (_VAL2FLD(UART0_IFLS_TXIFLSEL, 4)) // RX FIFO interrupt level settings. #define AM_HAL_UART_RX_FIFO_1_8 (_VAL2FLD(UART0_IFLS_RXIFLSEL, 0)) #define AM_HAL_UART_RX_FIFO_1_4 (_VAL2FLD(UART0_IFLS_RXIFLSEL, 1)) #define AM_HAL_UART_RX_FIFO_1_2 (_VAL2FLD(UART0_IFLS_RXIFLSEL, 2)) #define AM_HAL_UART_RX_FIFO_3_4 (_VAL2FLD(UART0_IFLS_RXIFLSEL, 3)) #define AM_HAL_UART_RX_FIFO_7_8 (_VAL2FLD(UART0_IFLS_RXIFLSEL, 4)) //***************************************************************************** // // UART interrupts. // //***************************************************************************** #define AM_HAL_UART_INT_OVER_RUN UART0_IER_OEIM_Msk #define AM_HAL_UART_INT_BREAK_ERR UART0_IER_BEIM_Msk #define AM_HAL_UART_INT_PARITY_ERR UART0_IER_PEIM_Msk #define AM_HAL_UART_INT_FRAME_ERR UART0_IER_FEIM_Msk #define AM_HAL_UART_INT_RX_TMOUT UART0_IER_RTIM_Msk #define AM_HAL_UART_INT_TX UART0_IER_TXIM_Msk #define AM_HAL_UART_INT_RX UART0_IER_RXIM_Msk #define AM_HAL_UART_INT_DSRM UART0_IER_DSRMIM_Msk #define AM_HAL_UART_INT_DCDM UART0_IER_DCDMIM_Msk #define AM_HAL_UART_INT_CTSM UART0_IER_CTSMIM_Msk #define AM_HAL_UART_INT_TXCMP UART0_IER_TXCMPMIM_Msk //***************************************************************************** // //! @name UART Flag Register //! @brief Macro definitions for UART Flag Register Bits. //! //! They may be used with the \e am_hal_uart_flags_get() function. //! //! @{ // //***************************************************************************** #define AM_HAL_UART_FR_TX_EMPTY (_VAL2FLD(UART0_FR_TXFE, UART0_FR_TXFE_XMTFIFO_EMPTY)) #define AM_HAL_UART_FR_RX_FULL (_VAL2FLD(UART0_FR_RXFF, UART0_FR_RXFF_RCVFIFO_FULL)) #define AM_HAL_UART_FR_TX_FULL (_VAL2FLD(UART0_FR_TXFF, UART0_FR_TXFF_XMTFIFO_FULL)) #define AM_HAL_UART_FR_RX_EMPTY (_VAL2FLD(UART0_FR_RXFE, UART0_FR_RXFE_RCVFIFO_EMPTY)) #define AM_HAL_UART_FR_BUSY (_VAL2FLD(UART0_FR_BUSY, UART0_FR_BUSY_BUSY)) #define AM_HAL_UART_FR_DCD_DETECTED (_VAL2FLD(UART0_FR_DCD, UART0_FR_DCD_DETECTED)) #define AM_HAL_UART_FR_DSR_READY (_VAL2FLD(UART0_FR_DSR, UART0_FR_DSR_READY)) #define AM_HAL_UART_FR_CTS UART0_FR_CTS_Msk //! @} //***************************************************************************** // // UART FIFO size for Apollo3. // //***************************************************************************** #define AM_HAL_UART_FIFO_MAX 32 //***************************************************************************** // // Turn timeouts into indefinite waits. // //***************************************************************************** #define AM_HAL_UART_WAIT_FOREVER 0xFFFFFFFF //***************************************************************************** // //! @brief Initialize the UART interface. //! //! @param ui32Module is the module number for the UART to initialize. //! @param ppHandle is the location to write the UART handle. //! //! This function sets internal tracking variables associated with a specific //! UART module. It should be the first UART API called for each UART module in //! use. The handle can be used to interact with the UART //! //! @return AM_HAL_STATUS_SUCCESS or applicable UART errors. // //***************************************************************************** extern uint32_t am_hal_uart_initialize(uint32_t ui32Module, void **ppHandle); //***************************************************************************** // //! @brief Deinitialize the UART interface. //! //! @param pHandle is a previously initialized UART handle. //! //! This function effectively disables future calls to interact with the UART //! refered to by \e pHandle. The user may call this function if UART operation //! is no longer desired. //! //! @return AM_HAL_STATUS_SUCCESS or applicable UART errors. // //***************************************************************************** extern uint32_t am_hal_uart_deinitialize(void *pHandle); //***************************************************************************** // //! @brief Change the power state of the UART module. //! //! @param pHandle is the handle for the UART to operate on. //! @param ePowerstate is the desired power state of the UART. //! @parame bRetainState is a flag to ask the HAL to save UART registers. //! //! This function can be used to switch the power to the UART on or off. If \e //! bRetainState is true during a powerdown operation, it will store the UART //! configuration registers to SRAM, so it can restore them on power-up. //! //! @return AM_HAL_STATUS_SUCCESS or applicable UART errors. // //***************************************************************************** extern uint32_t am_hal_uart_power_control(void *pHandle, am_hal_sysctrl_power_state_e ePowerState, bool bRetainState); //***************************************************************************** // //! @brief Used to configure basic UART settings. //! //! @param pHandle is the handle for the UART to operate on. //! @param psConfig is a structure of UART configuration options. //! //! This function takes the options from an \e am_hal_uart_config_t structure, //! and applies them to the UART referred to by \e pHandle. //! //! @return AM_HAL_STATUS_SUCCESS or applicable UART errors. // //***************************************************************************** extern uint32_t am_hal_uart_configure(void *pHandle, const am_hal_uart_config_t *psConfig); //***************************************************************************** // //! @brief Transfer data through the UART interface. //! //! @param pHandle is the handle for the UART to operate on. //! @param am_hal_uart_transfer_t is a structure describing the operation. //! //! This function executes a transaction as described by the \e //! am_hal_uart_transfer_t structure. It can either read or write, and it will //! take advantage of any buffer space provided by the \e //! am_hal_uart_configure() function. //! //! @return AM_HAL_STATUS_SUCCESS or applicable UART errors. // //***************************************************************************** extern uint32_t am_hal_uart_transfer(void *pHandle, const am_hal_uart_transfer_t *pTransfer); //***************************************************************************** // //! @brief Wait for the UART TX to become idle //! //! @param pHandle is the handle for the UART to operate on. //! //! This function waits (polling) for all data in the UART TX FIFO and UART TX //! buffer (if configured) to be fully sent on the physical UART interface. //! This is not the most power-efficient way to wait for UART idle, but it can be //! useful in simpler applications, or where power-efficiency is less important. //! //! Once this function returns, the UART can be safely disabled without //! interfering with any previous transmissions. //! //! For a more power-efficient way to shut down the UART, check the //! \e am_hal_uart_interrupt_service() function. //! //! @return AM_HAL_STATUS_SUCCESS or applicable UART errors. // //***************************************************************************** extern uint32_t am_hal_uart_tx_flush(void *pHandle); //***************************************************************************** // //! @brief Read the UART flags. //! //! @param pHandle is the handle for the UART to operate on. //! @param pui32Flags is the destination pointer for the UART flags. //! //! The UART hardware provides some information about the state of the physical //! interface at all times. This function provides a way to read that data //! directly. Below is a list of all possible UART flags. //! //! These correspond directly to the bits in the UART_FR register. //! //! @code //! //! AM_HAL_UART_FR_TX_EMPTY //! AM_HAL_UART_FR_RX_FULL //! AM_HAL_UART_FR_TX_FULL //! AM_HAL_UART_FR_RX_EMPTY //! AM_HAL_UART_FR_BUSY //! AM_HAL_UART_FR_DCD_DETECTED //! AM_HAL_UART_FR_DSR_READY //! AM_HAL_UART_FR_CTS //! //! @endcode //! //! @return AM_HAL_STATUS_SUCCESS or applicable UART errors. // //***************************************************************************** extern uint32_t am_hal_uart_flags_get(void *pHandle, uint32_t *pui32Flags); //***************************************************************************** // //! @brief Read the UART FIFO directly. //! //! @param pHandle is the handle for the UART to operate on. //! @param pui8Data is a pointer where the UART data should be written. //! @param ui32NumBytes is the number of bytes to transfer. //! @param pui32NumBytesRead is the nubmer of bytes actually transferred. //! //! This function reads the UART FIFO directly, and writes the resulting bytes //! to pui8Data. Since the UART FIFO hardware has no direct size indicator, the //! caller can only specify the maximum number of bytes they can handle. This //! function will try to read as many bytes as possible. At the end of the //! transfer, the number of bytes actually transferred will be written to the //! pui32NumBytesRead parameter. //! //! @return AM_HAL_STATUS_SUCCESS or applicable UART error. // //***************************************************************************** extern uint32_t am_hal_uart_fifo_read(void *pHandle, uint8_t *pui8Data, uint32_t ui32NumBytes, uint32_t *pui32NumBytesRead); //***************************************************************************** // //! @brief Write the UART FIFO directly. //! //! @param pHandle is the handle for the UART to operate on. //! @param pui8Data is a pointer where the UART data should be written. //! @param ui32NumBytes is the number of bytes to transfer. //! @param pui32NumBytesWritten is the nubmer of bytes actually transferred. //! //! This function reads from pui8Data, and writes the requested number of bytes //! directly to the UART FIFO. Since the UART FIFO hardware has no register to //! tell us how much free space it has, the caller can only specify the number //! of bytes they would like to send. This function will try to write as many //! bytes as possible up to the requested number. At the end of the transfer, //! the number of bytes actually transferred will be written to the //! pui32NumBytesWritten parameter. //! //! @return AM_HAL_STATUS_SUCCESS or applicable UART error. // //***************************************************************************** extern uint32_t am_hal_uart_fifo_write(void *pHandle, uint8_t *pui8Data, uint32_t ui32NumBytes, uint32_t *pui32NumBytesWritten); //***************************************************************************** // //! @brief This function handles the UART buffers during UART interrupts. //! //! @param pHandle is the handle for the UART to operate on. //! @param ui32Status is the interrupt status at the time of ISR entry. //! @param pui32UartTxIdle can be used to store the UART idle status. //! //! The main purpose of this function is to manage the UART buffer system. Any //! buffers configured by \e am_hal_uart_buffer_configure will be managed by //! this service routine. Data queued for transmit will be added to the UART TX //! FIFO as space allows, and data stored in the UART RX FIFO will be copied //! out and stored in the RX buffer. This function will skip this transfer for //! any buffer that has not been configured. //! //! In addition, this function can be used to alert the caller when the UART //! becomes idle via the optional \e pui32UartTxIdle argument. This function //! will set this variable any time it completes its operation and the UART TX //! channel is no longer in use (including both the FIFO and any configured //! buffer). To make sure this happens as early as possible, the user may //! enable the UART_TXCMP interrupt as shown below. //! //! For RTOS-enabled cases, this function does not necessarily need to be //! called inside the actual ISR for the UART, but it should be called promptly //! in response to the receipt of a UART TX, RX, or RX timeout interrupt. If //! the service routine is not called quickly enough, the caller risks an RX //! FIFO overflow (data can be lost here), or a TX FIFO underflow (usually not //! harmful). //! //! @code //! //! void //! am_uart_isr(void) //! { //! // //! // Service the FIFOs as necessary, and clear the interrupts. //! // //! uint32_t ui32Status; //! uint32_t ui32UartIdle; //! //! am_hal_uart_interrupt_status_get(UART, &ui32Status, true); //! am_hal_uart_interrupt_clear(UART, ui32Status); //! am_hal_uart_interrupt_service(UART, ui32Status, &ui32UartIdle); //! //! ui32TXDoneFlag = ui32UartIdle; //! } //! //! int //! main(void) //! { //! ... //! //! // Initialize, power up, and configure the UART. //! am_hal_uart_initialize(0, &UART); //! am_hal_uart_power_control(UART, AM_HAL_SYSCTRL_WAKE, false); //! am_hal_uart_configure(UART, &sUartConfig); //! //! ... //! //! // Enable the UART0 interrupt vector. //! am_hal_uart_interrupt_enable(UART, AM_REG_UART_IER_TXCMPMIM_M); //! am_hal_interrupt_enable(AM_HAL_INTERRUPT_UART0); //! am_hal_interrupt_master_enable(); //! } //! //! //! @endcode //! //! @return AM_HAL_STATUS_SUCCESS or applicable UART errors. // //***************************************************************************** extern uint32_t am_hal_uart_interrupt_service(void *pHandle, uint32_t ui32Status, uint32_t *pui32UartTxIdle); //***************************************************************************** // //! @brief Enable interrupts. //! //! @param pHandle is the handle for the UART to operate on. //! @param ui32IntMask is the bitmask of interrupts to enable. //! //! This function enables the UART interrupt(s) given by ui32IntMask. If //! multiple interrupts are desired, they can be OR'ed together. //! //! @note This function need not be called for UART FIFO interrupts if the UART //! buffer service provided by \e am_hal_uart_buffer_configure() and \e //! am_hal_uart_interrupt_service() is already in use. Non-FIFO-related //! interrupts do require the use of this function. //! //! The full list of interrupts is given by the following: //! //! @code //! //! AM_HAL_UART_INT_OVER_RUN //! AM_HAL_UART_INT_BREAK_ERR //! AM_HAL_UART_INT_PARITY_ERR //! AM_HAL_UART_INT_FRAME_ERR //! AM_HAL_UART_INT_RX_TMOUT //! AM_HAL_UART_INT_TX //! AM_HAL_UART_INT_RX //! AM_HAL_UART_INT_DSRM //! AM_HAL_UART_INT_DCDM //! AM_HAL_UART_INT_CTSM //! AM_HAL_UART_INT_TXCMP //! //! @endcode //! //! @return AM_HAL_STATUS_SUCCESS or applicable UART errors. // //***************************************************************************** extern uint32_t am_hal_uart_interrupt_enable(void *pHandle, uint32_t ui32IntMask); //***************************************************************************** // //! @brief Disable interrupts. //! //! @param pHandle is the handle for the UART to operate on. //! @param ui32IntMask is the bitmask of interrupts to disable. //! //! This function disables the UART interrupt(s) given by ui32IntMask. If //! multiple interrupts need to be disabled, they can be OR'ed together. //! //! @note This function need not be called for UART FIFO interrupts if the UART //! buffer service provided by \e am_hal_uart_buffer_configure() and \e //! am_hal_uart_interrupt_service() is already in use. Non-FIFO-related //! interrupts do require the use of this function. //! //! The full list of interrupts is given by the following: //! //! @code //! //! AM_HAL_UART_INT_OVER_RUN //! AM_HAL_UART_INT_BREAK_ERR //! AM_HAL_UART_INT_PARITY_ERR //! AM_HAL_UART_INT_FRAME_ERR //! AM_HAL_UART_INT_RX_TMOUT //! AM_HAL_UART_INT_TX //! AM_HAL_UART_INT_RX //! AM_HAL_UART_INT_DSRM //! AM_HAL_UART_INT_DCDM //! AM_HAL_UART_INT_CTSM //! AM_HAL_UART_INT_TXCMP //! //! @endcode //! //! @return AM_HAL_STATUS_SUCCESS or applicable UART errors. // //***************************************************************************** extern uint32_t am_hal_uart_interrupt_disable(void *pHandle, uint32_t ui32IntMask); //***************************************************************************** // //! @brief Clear interrupt status. //! //! @param pHandle is the handle for the UART to operate on. //! @param ui32IntMask is the bitmask of interrupts to clear. //! //! This function clears the UART interrupt(s) given by ui32IntMask. If //! multiple interrupts need to be cleared, they can be OR'ed together. //! //! The full list of interrupts is given by the following: //! //! @code //! //! AM_HAL_UART_INT_OVER_RUN //! AM_HAL_UART_INT_BREAK_ERR //! AM_HAL_UART_INT_PARITY_ERR //! AM_HAL_UART_INT_FRAME_ERR //! AM_HAL_UART_INT_RX_TMOUT //! AM_HAL_UART_INT_TX //! AM_HAL_UART_INT_RX //! AM_HAL_UART_INT_DSRM //! AM_HAL_UART_INT_DCDM //! AM_HAL_UART_INT_CTSM //! AM_HAL_UART_INT_TXCMP //! //! @endcode //! //! @return AM_HAL_STATUS_SUCCESS or applicable UART errors. // //***************************************************************************** extern uint32_t am_hal_uart_interrupt_clear(void *pHandle, uint32_t ui32IntMask); //***************************************************************************** // //! @brief Read interrupt status. //! //! @param pHandle is the handle for the UART to operate on. //! //! @param pui32Status is the returned interrupt status (all bits OR'ed //! together) //! //! @param bEnabled determines whether to read interrupts that were not //! enabled. //! //! This function reads the status the UART interrupt(s) if \e bEnabled is //! true, it will only return the status of the enabled interrupts. Otherwise, //! it will return the status of all interrupts, enabled or disabled. //! //! The full list of interrupts is given by the following: //! //! @code //! //! AM_HAL_UART_INT_OVER_RUN //! AM_HAL_UART_INT_BREAK_ERR //! AM_HAL_UART_INT_PARITY_ERR //! AM_HAL_UART_INT_FRAME_ERR //! AM_HAL_UART_INT_RX_TMOUT //! AM_HAL_UART_INT_TX //! AM_HAL_UART_INT_RX //! AM_HAL_UART_INT_DSRM //! AM_HAL_UART_INT_DCDM //! AM_HAL_UART_INT_CTSM //! AM_HAL_UART_INT_TXCMP //! //! @endcode //! //! @return AM_HAL_STATUS_SUCCESS or applicable UART errors. // //***************************************************************************** extern uint32_t am_hal_uart_interrupt_status_get(void *pHandle, uint32_t *pui32Status, bool bEnabledOnly); typedef enum { AM_HAL_UART_STATUS_BUS_ERROR = AM_HAL_STATUS_MODULE_SPECIFIC_START, AM_HAL_UART_STATUS_RX_QUEUE_FULL, AM_HAL_UART_STATUS_CLOCK_NOT_CONFIGURED, AM_HAL_UART_STATUS_BAUDRATE_NOT_POSSIBLE, } am_hal_uart_errors_t; //***************************************************************************** // //! @brief Check to see which interrupts are enabled. //! //! @param pHandle is the handle for the UART to operate on. //! //! @param pui32IntMask is the current set of interrupt enable bits (all bits //! OR'ed together) //! //! This function checks the UART Interrupt Enable Register to see which UART //! interrupts are currently enabled. The result will be an interrupt mask with //! one bit set for each of the currently enabled UART interrupts. //! //! The full set of UART interrupt bits is given by the list below: //! //! @code //! //! AM_HAL_UART_INT_OVER_RUN //! AM_HAL_UART_INT_BREAK_ERR //! AM_HAL_UART_INT_PARITY_ERR //! AM_HAL_UART_INT_FRAME_ERR //! AM_HAL_UART_INT_RX_TMOUT //! AM_HAL_UART_INT_TX //! AM_HAL_UART_INT_RX //! AM_HAL_UART_INT_DSRM //! AM_HAL_UART_INT_DCDM //! AM_HAL_UART_INT_CTSM //! AM_HAL_UART_INT_TXCMP //! //! @endcode //! //! @return AM_HAL_STATUS_SUCCESS or applicable UART errors. // //***************************************************************************** extern uint32_t am_hal_uart_interrupt_enable_get(void *pHandle, uint32_t *pui32IntMask); #ifdef __cplusplus } #endif #endif // AM_HAL_UART_H //***************************************************************************** // // End Doxygen group. //! @} // //*****************************************************************************