/* ChibiOS/RT - Copyright (C) 2006,2007,2008,2009,2010, 2011,2012,2013 Giovanni Di Sirio. This file is part of ChibiOS/RT. ChibiOS/RT is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. ChibiOS/RT is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ /** * @file hal_queues.h * @brief I/O Queues macros and structures. * * @addtogroup io_queues * @{ */ #ifndef _HAL_QUEUES_H_ #define _HAL_QUEUES_H_ /* The ChibiOS/RT kernel provides the following definitions by itself, this check is performed in order to avoid conflicts. */ #if !defined(_CHIBIOS_RT_) || !CH_CFG_USE_QUEUES /** * @name Queue functions returned status value * @{ */ #define Q_OK MSG_OK /**< @brief Operation successful. */ #define Q_TIMEOUT MSG_TIMEOUT /**< @brief Timeout condition. */ #define Q_RESET MSG_RESET /**< @brief Queue has been reset. */ #define Q_EMPTY -3 /**< @brief Queue empty. */ #define Q_FULL -4 /**< @brief Queue full, */ /** @} */ /** * @brief Type of a generic I/O queue structure. */ typedef struct io_queue_t io_queue_t; /** @brief Queue notification callback type.*/ typedef void (*qnotify_t)(io_queue_t *qp); /** * @brief Generic I/O queue structure. * @details This structure represents a generic Input or Output asymmetrical * queue. The queue is asymmetrical because one end is meant to be * accessed from a thread context, and thus can be blocking, the other * end is accessible from interrupt handlers or from within a kernel * lock zone (see I-Locked and S-Locked states in * @ref system_states) and is non-blocking. */ struct io_queue_t { threads_queue_t q_waiting; /**< @brief Waiting thread. */ size_t q_counter; /**< @brief Resources counter. */ uint8_t *q_buffer; /**< @brief Pointer to the queue buffer.*/ uint8_t *q_top; /**< @brief Pointer to the first location after the buffer. */ uint8_t *q_wrptr; /**< @brief Write pointer. */ uint8_t *q_rdptr; /**< @brief Read pointer. */ qnotify_t q_notify; /**< @brief Data notification callback. */ void *q_link; /**< @brief Application defined field. */ }; /** * @name Macro Functions * @{ */ /** * @brief Returns the queue's buffer size. * * @param[in] qp pointer to a @p io_queue_t structure. * @return The buffer size. * * @iclass */ #define qSizeI(qp) ((size_t)((qp)->q_top - (qp)->q_buffer)) /** * @brief Queue space. * @details Returns the used space if used on an input queue or the empty * space if used on an output queue. * * @param[in] qp pointer to a @p io_queue_t structure. * @return The buffer space. * * @iclass */ #define qSpaceI(qp) ((qp)->q_counter) /** * @brief Returns the queue application-defined link. * @note This function can be called in any context. * * @param[in] qp pointer to a @p io_queue_t structure. * @return The application-defined link. * * @special */ #define qGetLink(qp) ((qp)->q_link) /** @} */ /** * @extends io_queue_t * * @brief Type of an input queue structure. * @details This structure represents a generic asymmetrical input queue. * Writing to the queue is non-blocking and can be performed from * interrupt handlers or from within a kernel lock zone (see * I-Locked and S-Locked states in @ref system_states). * Reading the queue can be a blocking operation and is supposed to * be performed by a system thread. */ typedef io_queue_t input_queue_t; /** * @name Macro Functions * @{ */ /** * @brief Returns the filled space into an input queue. * * @param[in] iqp pointer to an @p input_queue_t structure * @return The number of full bytes in the queue. * @retval 0 if the queue is empty. * * @iclass */ #define iqGetFullI(iqp) qSpaceI(iqp) /** * @brief Returns the empty space into an input queue. * * @param[in] iqp pointer to an @p input_queue_t structure * @return The number of empty bytes in the queue. * @retval 0 if the queue is full. * * @iclass */ #define iqGetEmptyI(iqp) (qSizeI(iqp) - qSpaceI(iqp)) /** * @brief Evaluates to @p TRUE if the specified input queue is empty. * * @param[in] iqp pointer to an @p input_queue_t structure. * @return The queue status. * @retval FALSE if the queue is not empty. * @retval TRUE if the queue is empty. * * @iclass */ #define iqIsEmptyI(iqp) ((bool)(qSpaceI(iqp) <= 0)) /** * @brief Evaluates to @p TRUE if the specified input queue is full. * * @param[in] iqp pointer to an @p input_queue_t structure. * @return The queue status. * @retval FALSE if the queue is not full. * @retval TRUE if the queue is full. * * @iclass */ #define iqIsFullI(iqp) ((bool)(((iqp)->q_wrptr == (iqp)->q_rdptr) && \ ((iqp)->q_counter != 0))) /** * @brief Input queue read. * @details This function reads a byte value from an input queue. If the queue * is empty then the calling thread is suspended until a byte arrives * in the queue. * * @param[in] iqp pointer to an @p input_queue_t structure * @return A byte value from the queue. * @retval Q_RESET if the queue has been reset. * * @api */ #define iqGet(iqp) iqGetTimeout(iqp, TIME_INFINITE) /** @} */ /** * @brief Data part of a static input queue initializer. * @details This macro should be used when statically initializing an * input queue that is part of a bigger structure. * * @param[in] name the name of the input queue variable * @param[in] buffer pointer to the queue buffer area * @param[in] size size of the queue buffer area * @param[in] inotify input notification callback pointer * @param[in] link application defined pointer */ #define _INPUTQUEUE_DATA(name, buffer, size, inotify, link) { \ NULL, \ 0, \ (uint8_t *)(buffer), \ (uint8_t *)(buffer) + (size), \ (uint8_t *)(buffer), \ (uint8_t *)(buffer), \ (inotify), \ (link) \ } /** * @brief Static input queue initializer. * @details Statically initialized input queues require no explicit * initialization using @p iqInit(). * * @param[in] name the name of the input queue variable * @param[in] buffer pointer to the queue buffer area * @param[in] size size of the queue buffer area * @param[in] inotify input notification callback pointer * @param[in] link application defined pointer */ #define INPUTQUEUE_DECL(name, buffer, size, inotify, link) \ input_queue_t name = _INPUTQUEUE_DATA(name, buffer, size, inotify, link) /** * @extends io_queue_t * * @brief Type of an output queue structure. * @details This structure represents a generic asymmetrical output queue. * Reading from the queue is non-blocking and can be performed from * interrupt handlers or from within a kernel lock zone (see * I-Locked and S-Locked states in @ref system_states). * Writing the queue can be a blocking operation and is supposed to * be performed by a system thread. */ typedef io_queue_t output_queue_t; /** * @name Macro Functions * @{ */ /** * @brief Returns the filled space into an output queue. * * @param[in] oqp pointer to an @p output_queue_t structure * @return The number of full bytes in the queue. * @retval 0 if the queue is empty. * * @iclass */ #define oqGetFullI(oqp) (qSizeI(oqp) - qSpaceI(oqp)) /** * @brief Returns the empty space into an output queue. * * @param[in] oqp pointer to an @p output_queue_t structure * @return The number of empty bytes in the queue. * @retval 0 if the queue is full. * * @iclass */ #define oqGetEmptyI(oqp) qSpaceI(oqp) /** * @brief Evaluates to @p TRUE if the specified output queue is empty. * * @param[in] oqp pointer to an @p output_queue_t structure. * @return The queue status. * @retval FALSE if the queue is not empty. * @retval TRUE if the queue is empty. * * @iclass */ #define oqIsEmptyI(oqp) ((bool)(((oqp)->q_wrptr == (oqp)->q_rdptr) && \ ((oqp)->q_counter != 0))) /** * @brief Evaluates to @p TRUE if the specified output queue is full. * * @param[in] oqp pointer to an @p output_queue_t structure. * @return The queue status. * @retval FALSE if the queue is not full. * @retval TRUE if the queue is full. * * @iclass */ #define oqIsFullI(oqp) ((bool)(qSpaceI(oqp) <= 0)) /** * @brief Output queue write. * @details This function writes a byte value to an output queue. If the queue * is full then the calling thread is suspended until there is space * in the queue. * * @param[in] oqp pointer to an @p output_queue_t structure * @param[in] b the byte value to be written in the queue * @return The operation status. * @retval Q_OK if the operation succeeded. * @retval Q_RESET if the queue has been reset. * * @api */ #define oqPut(oqp, b) oqPutTimeout(oqp, b, TIME_INFINITE) /** @} */ /** * @brief Data part of a static output queue initializer. * @details This macro should be used when statically initializing an * output queue that is part of a bigger structure. * * @param[in] name the name of the output queue variable * @param[in] buffer pointer to the queue buffer area * @param[in] size size of the queue buffer area * @param[in] onotify output notification callback pointer * @param[in] link application defined pointer */ #define _OUTPUTQUEUE_DATA(name, buffer, size, onotify, link) { \ NULL, \ (size), \ (uint8_t *)(buffer), \ (uint8_t *)(buffer) + (size), \ (uint8_t *)(buffer), \ (uint8_t *)(buffer), \ (onotify), \ (link) \ } /** * @brief Static output queue initializer. * @details Statically initialized output queues require no explicit * initialization using @p oqInit(). * * @param[in] name the name of the output queue variable * @param[in] buffer pointer to the queue buffer area * @param[in] size size of the queue buffer area * @param[in] onotify output notification callback pointer * @param[in] link application defined pointer */ #define OUTPUTQUEUE_DECL(name, buffer, size, onotify, link) \ output_queue_t name = _OUTPUTQUEUE_DATA(name, buffer, size, onotify, link) #ifdef __cplusplus extern "C" { #endif void iqObjectInit(input_queue_t *iqp, uint8_t *bp, size_t size, qnotify_t infy, void *link); void iqResetI(input_queue_t *iqp); msg_t iqPutI(input_queue_t *iqp, uint8_t b); msg_t iqGetTimeout(input_queue_t *iqp, systime_t time); size_t iqReadTimeout(input_queue_t *iqp, uint8_t *bp, size_t n, systime_t time); void oqObjectInit(output_queue_t *oqp, uint8_t *bp, size_t size, qnotify_t onfy, void *link); void oqResetI(output_queue_t *oqp); msg_t oqPutTimeout(output_queue_t *oqp, uint8_t b, systime_t time); msg_t oqGetI(output_queue_t *oqp); size_t oqWriteTimeout(output_queue_t *oqp, const uint8_t *bp, size_t n, systime_t time); #ifdef __cplusplus } #endif #else /* defined(_CHIBIOS_RT_) && CH_USE_QUEUES */ /* If ChibiOS is being used and its own queues subsystem is activated then this module will use the ChibiOS queues code.*/ #define qSizeI(qp) chQSizeI(qp) #define qSpaceI(qp) chQSpaceI(qp) #define qGetLink(qp) chQGetLinkX(qp) #define iqGetFullI(iqp) chIQGetFullI(iqp) #define iqGetEmptyI(iqp) chIQGetEmptyI(iqp) #define iqIsEmptyI(iqp) chIQIsEmptyI(iqp) #define iqIsFullI(iqp) chIQIsFullI(iqp) #define iqGet(iqp) chIQGet(iqp) #define oqGetFullI(oqp) chOQGetFullI(oqp) #define oqGetEmptyI(oqp) chOQGetEmptyI(oqp) #define oqIsEmptyI(oqp) chOQIsEmptyI(oqp) #define oqIsFullI(oqp) chOQIsFullI(oqp) #define oqPut(oqp, b) chOQPut(oqp, b) #define iqObjectInit(iqp, bp, size, infy, link) \ chIQObjectInit(iqp, bp, size, infy, link) #define iqResetI(iqp) chIQResetI(iqp) #define iqPutI(iqp, b) chIQPutI(iqp, b) #define iqGetTimeout(iqp, time) chIQGetTimeout(iqp, time) #define iqReadTimeout(iqp, bp, n, time) chIQReadTimeout(iqp, bp, n, time) #define oqObjectInit(oqp, bp, size, onfy, link) \ chOQObjectInit(oqp, bp, size, onfy, link) #define oqResetI(oqp) chOQResetI(oqp) #define oqPutTimeout(oqp, b, time) chOQPutTimeout(oqp, b, time) #define oqGetI(oqp) chOQGetI(oqp) #define oqWriteTimeout(oqp, bp, n, time) chOQWriteTimeout(oqp, bp, n, time) #endif /* defined(_CHIBIOS_RT_) && CH_USE_QUEUES */ #endif /* _HAL_QUEUES_H_ */ /** @} */