/* ChibiOS - Copyright (C) 2006..2016 Giovanni Di Sirio Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. */ /** * @file hal_uart.c * @brief UART Driver code. * * @addtogroup UART * @{ */ #include "hal.h" #if (HAL_USE_UART == TRUE) || defined(__DOXYGEN__) /*===========================================================================*/ /* Driver local definitions. */ /*===========================================================================*/ /*===========================================================================*/ /* Driver exported variables. */ /*===========================================================================*/ /*===========================================================================*/ /* Driver local variables and types. */ /*===========================================================================*/ /*===========================================================================*/ /* Driver local functions. */ /*===========================================================================*/ /*===========================================================================*/ /* Driver exported functions. */ /*===========================================================================*/ /** * @brief UART Driver initialization. * @note This function is implicitly invoked by @p halInit(), there is * no need to explicitly initialize the driver. * * @init */ void uartInit(void) { uart_lld_init(); } /** * @brief Initializes the standard part of a @p UARTDriver structure. * * @param[out] uartp pointer to the @p UARTDriver object * * @init */ void uartObjectInit(UARTDriver *uartp) { uartp->state = UART_STOP; uartp->txstate = UART_TX_IDLE; uartp->rxstate = UART_RX_IDLE; uartp->config = NULL; #if UART_USE_WAIT == TRUE uartp->early = false; uartp->threadrx = NULL; uartp->threadtx = NULL; #endif /* UART_USE_WAIT */ #if UART_USE_MUTUAL_EXCLUSION == TRUE osalMutexObjectInit(&uartp->mutex); #endif /* UART_USE_MUTUAL_EXCLUSION */ /* Optional, user-defined initializer.*/ #if defined(UART_DRIVER_EXT_INIT_HOOK) UART_DRIVER_EXT_INIT_HOOK(uartp); #endif } /** * @brief Configures and activates the UART peripheral. * * @param[in] uartp pointer to the @p UARTDriver object * @param[in] config pointer to the @p UARTConfig object * * @api */ void uartStart(UARTDriver *uartp, const UARTConfig *config) { osalDbgCheck((uartp != NULL) && (config != NULL)); osalSysLock(); osalDbgAssert((uartp->state == UART_STOP) || (uartp->state == UART_READY), "invalid state"); uartp->config = config; uart_lld_start(uartp); uartp->state = UART_READY; osalSysUnlock(); } /** * @brief Deactivates the UART peripheral. * * @param[in] uartp pointer to the @p UARTDriver object * * @api */ void uartStop(UARTDriver *uartp) { osalDbgCheck(uartp != NULL); osalSysLock(); osalDbgAssert((uartp->state == UART_STOP) || (uartp->state == UART_READY), "invalid state"); uart_lld_stop(uartp); uartp->config = NULL; uartp->state = UART_STOP; uartp->txstate = UART_TX_IDLE; uartp->rxstate = UART_RX_IDLE; osalSysUnlock(); } /** * @brief Starts a transmission on the UART peripheral. * @note The buffers are organized as uint8_t arrays for data sizes below * or equal to 8 bits else it is organized as uint16_t arrays. * * @param[in] uartp pointer to the @p UARTDriver object * @param[in] n number of data frames to send * @param[in] txbuf the pointer to the transmit buffer * * @api */ void uartStartSend(UARTDriver *uartp, size_t n, const void *txbuf) { osalDbgCheck((uartp != NULL) && (n > 0U) && (txbuf != NULL)); osalSysLock(); osalDbgAssert(uartp->state == UART_READY, "is active"); osalDbgAssert(uartp->txstate != UART_TX_ACTIVE, "tx active"); uart_lld_start_send(uartp, n, txbuf); uartp->txstate = UART_TX_ACTIVE; osalSysUnlock(); } /** * @brief Starts a transmission on the UART peripheral. * @note The buffers are organized as uint8_t arrays for data sizes below * or equal to 8 bits else it is organized as uint16_t arrays. * @note This function has to be invoked from a lock zone. * * @param[in] uartp pointer to the @p UARTDriver object * @param[in] n number of data frames to send * @param[in] txbuf the pointer to the transmit buffer * * @iclass */ void uartStartSendI(UARTDriver *uartp, size_t n, const void *txbuf) { osalDbgCheckClassI(); osalDbgCheck((uartp != NULL) && (n > 0U) && (txbuf != NULL)); osalDbgAssert(uartp->state == UART_READY, "is active"); osalDbgAssert(uartp->txstate != UART_TX_ACTIVE, "tx active"); uart_lld_start_send(uartp, n, txbuf); uartp->txstate = UART_TX_ACTIVE; } /** * @brief Stops any ongoing transmission. * @note Stopping a transmission also suppresses the transmission callbacks. * * @param[in] uartp pointer to the @p UARTDriver object * * @return The number of data frames not transmitted by the * stopped transmit operation. * @retval 0 There was no transmit operation in progress. * * @api */ size_t uartStopSend(UARTDriver *uartp) { size_t n; osalDbgCheck(uartp != NULL); osalSysLock(); osalDbgAssert(uartp->state == UART_READY, "not active"); if (uartp->txstate == UART_TX_ACTIVE) { n = uart_lld_stop_send(uartp); uartp->txstate = UART_TX_IDLE; } else { n = 0; } osalSysUnlock(); return n; } /** * @brief Stops any ongoing transmission. * @note Stopping a transmission also suppresses the transmission callbacks. * @note This function has to be invoked from a lock zone. * * @param[in] uartp pointer to the @p UARTDriver object * * @return The number of data frames not transmitted by the * stopped transmit operation. * @retval 0 There was no transmit operation in progress. * * @iclass */ size_t uartStopSendI(UARTDriver *uartp) { osalDbgCheckClassI(); osalDbgCheck(uartp != NULL); osalDbgAssert(uartp->state == UART_READY, "not active"); if (uartp->txstate == UART_TX_ACTIVE) { size_t n = uart_lld_stop_send(uartp); uartp->txstate = UART_TX_IDLE; return n; } return 0; } /** * @brief Starts a receive operation on the UART peripheral. * @note The buffers are organized as uint8_t arrays for data sizes below * or equal to 8 bits else it is organized as uint16_t arrays. * * @param[in] uartp pointer to the @p UARTDriver object * @param[in] n number of data frames to receive * @param[in] rxbuf the pointer to the receive buffer * * @api */ void uartStartReceive(UARTDriver *uartp, size_t n, void *rxbuf) { osalDbgCheck((uartp != NULL) && (n > 0U) && (rxbuf != NULL)); osalSysLock(); osalDbgAssert(uartp->state == UART_READY, "is active"); osalDbgAssert(uartp->rxstate != UART_RX_ACTIVE, "rx active"); uart_lld_start_receive(uartp, n, rxbuf); uartp->rxstate = UART_RX_ACTIVE; osalSysUnlock(); } /** * @brief Starts a receive operation on the UART peripheral. * @note The buffers are organized as uint8_t arrays for data sizes below * or equal to 8 bits else it is organized as uint16_t arrays. * @note This function has to be invoked from a lock zone. * * @param[in] uartp pointer to the @p UARTDriver object * @param[in] n number of data frames to receive * @param[out] rxbuf the pointer to the receive buffer * * @iclass */ void uartStartReceiveI(UARTDriver *uartp, size_t n, void *rxbuf) { osalDbgCheckClassI(); osalDbgCheck((uartp != NULL) && (n > 0U) && (rxbuf != NULL)); osalDbgAssert(uartp->state == UART_READY, "is active"); osalDbgAssert(uartp->rxstate != UART_RX_ACTIVE, "rx active"); uart_lld_start_receive(uartp, n, rxbuf); uartp->rxstate = UART_RX_ACTIVE; } /** * @brief Stops any ongoing receive operation. * @note Stopping a receive operation also suppresses the receive callbacks. * * @param[in] uartp pointer to the @p UARTDriver object * * @return The number of data frames not received by the * stopped receive operation. * @retval 0 There was no receive operation in progress. * * @api */ size_t uartStopReceive(UARTDriver *uartp) { size_t n; osalDbgCheck(uartp != NULL); osalSysLock(); osalDbgAssert(uartp->state == UART_READY, "not active"); if (uartp->rxstate == UART_RX_ACTIVE) { n = uart_lld_stop_receive(uartp); uartp->rxstate = UART_RX_IDLE; } else { n = 0; } osalSysUnlock(); return n; } /** * @brief Stops any ongoing receive operation. * @note Stopping a receive operation also suppresses the receive callbacks. * @note This function has to be invoked from a lock zone. * * @param[in] uartp pointer to the @p UARTDriver object * * @return The number of data frames not received by the * stopped receive operation. * @retval 0 There was no receive operation in progress. * * @iclass */ size_t uartStopReceiveI(UARTDriver *uartp) { osalDbgCheckClassI(); osalDbgCheck(uartp != NULL); osalDbgAssert(uartp->state == UART_READY, "not active"); if (uartp->rxstate == UART_RX_ACTIVE) { size_t n = uart_lld_stop_receive(uartp); uartp->rxstate = UART_RX_IDLE; return n; } return 0; } #if (UART_USE_WAIT == TRUE) || defined(__DOXYGEN__) /** * @brief Performs a transmission on the UART peripheral. * @note The function returns when the specified number of frames have been * sent to the UART or on timeout. * @note The buffers are organized as uint8_t arrays for data sizes below * or equal to 8 bits else it is organized as uint16_t arrays. * @note This function implements a software timeout, it does not use * any underlying HW timeout mechanism. * * @param[in] uartp pointer to the @p UARTDriver object * @param[in,out] np number of data frames to transmit, on exit the number * of frames actually transmitted * @param[in] txbuf the pointer to the transmit buffer * @param[in] timeout operation timeout * @return The operation status. * @retval MSG_OK if the operation completed successfully. * @retval MSG_TIMEOUT if the operation timed out. * * @api */ msg_t uartSendTimeout(UARTDriver *uartp, size_t *np, const void *txbuf, sysinterval_t timeout) { msg_t msg; osalDbgCheck((uartp != NULL) && (*np > 0U) && (txbuf != NULL)); osalSysLock(); osalDbgAssert(uartp->state == UART_READY, "is active"); osalDbgAssert(uartp->txstate != UART_TX_ACTIVE, "tx active"); /* Transmission start.*/ uartp->early = true; uart_lld_start_send(uartp, *np, txbuf); uartp->txstate = UART_TX_ACTIVE; /* Waiting for result.*/ msg = osalThreadSuspendTimeoutS(&uartp->threadtx, timeout); if (msg != MSG_OK) { *np -= uartStopSendI(uartp); } osalSysUnlock(); return msg; } /** * @brief Performs a transmission on the UART peripheral. * @note The function returns when the specified number of frames have been * physically transmitted or on timeout. * @note The buffers are organized as uint8_t arrays for data sizes below * or equal to 8 bits else it is organized as uint16_t arrays. * @note This function implements a software timeout, it does not use * any underlying HW timeout mechanism. * * @param[in] uartp pointer to the @p UARTDriver object * @param[in,out] np number of data frames to transmit, on exit the number * of frames actually transmitted * @param[in] txbuf the pointer to the transmit buffer * @param[in] timeout operation timeout * @return The operation status. * @retval MSG_OK if the operation completed successfully. * @retval MSG_TIMEOUT if the operation timed out. * * @api */ msg_t uartSendFullTimeout(UARTDriver *uartp, size_t *np, const void *txbuf, sysinterval_t timeout) { msg_t msg; osalDbgCheck((uartp != NULL) && (*np > 0U) && (txbuf != NULL)); osalSysLock(); osalDbgAssert(uartp->state == UART_READY, "is active"); osalDbgAssert(uartp->txstate != UART_TX_ACTIVE, "tx active"); /* Transmission start.*/ uartp->early = false; uart_lld_start_send(uartp, *np, txbuf); uartp->txstate = UART_TX_ACTIVE; /* Waiting for result.*/ msg = osalThreadSuspendTimeoutS(&uartp->threadtx, timeout); if (msg != MSG_OK) { *np = uartStopSendI(uartp); } osalSysUnlock(); return msg; } /** * @brief Performs a receive operation on the UART peripheral. * @note The function returns when the specified number of frames have been * received or on error/timeout. * @note The buffers are organized as uint8_t arrays for data sizes below * or equal to 8 bits else it is organized as uint16_t arrays. * @note This function implements a software timeout, it does not use * any underlying HW timeout mechanism. * * @param[in] uartp pointer to the @p UARTDriver object * @param[in,out] np number of data frames to receive, on exit the number * of frames actually received * @param[in] rxbuf the pointer to the receive buffer * @param[in] timeout operation timeout * * @return The operation status. * @retval MSG_OK if the operation completed successfully. * @retval MSG_TIMEOUT if the operation timed out. * @retval MSG_RESET in case of a receive error. * * @api */ msg_t uartReceiveTimeout(UARTDriver *uartp, size_t *np, void *rxbuf, sysinterval_t timeout) { msg_t msg; osalDbgCheck((uartp != NULL) && (*np > 0U) && (rxbuf != NULL)); osalSysLock(); osalDbgAssert(uartp->state == UART_READY, "is active"); osalDbgAssert(uartp->rxstate != UART_RX_ACTIVE, "rx active"); /* Receive start.*/ uart_lld_start_receive(uartp, *np, rxbuf); uartp->rxstate = UART_RX_ACTIVE; /* Waiting for result.*/ msg = osalThreadSuspendTimeoutS(&uartp->threadrx, timeout); if (msg != MSG_OK) { *np -= uartStopReceiveI(uartp); } osalSysUnlock(); return msg; } #endif #if (UART_USE_MUTUAL_EXCLUSION == TRUE) || defined(__DOXYGEN__) /** * @brief Gains exclusive access to the UART bus. * @details This function tries to gain ownership to the UART bus, if the bus * is already being used then the invoking thread is queued. * @pre In order to use this function the option @p UART_USE_MUTUAL_EXCLUSION * must be enabled. * * @param[in] uartp pointer to the @p UARTDriver object * * @api */ void uartAcquireBus(UARTDriver *uartp) { osalDbgCheck(uartp != NULL); osalMutexLock(&uartp->mutex); } /** * @brief Releases exclusive access to the UART bus. * @pre In order to use this function the option @p UART_USE_MUTUAL_EXCLUSION * must be enabled. * * @param[in] uartp pointer to the @p UARTDriver object * * @api */ void uartReleaseBus(UARTDriver *uartp) { osalDbgCheck(uartp != NULL); osalMutexUnlock(&uartp->mutex); } #endif #endif /* HAL_USE_UART == TRUE */ /** @} */