Martin Cottrell
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Lancaster University
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app_scheduler.c
00001 /* 00002 * Copyright (c) Nordic Semiconductor ASA 00003 * All rights reserved. 00004 * 00005 * Redistribution and use in source and binary forms, with or without modification, 00006 * are permitted provided that the following conditions are met: 00007 * 00008 * 1. Redistributions of source code must retain the above copyright notice, this 00009 * list of conditions and the following disclaimer. 00010 * 00011 * 2. Redistributions in binary form must reproduce the above copyright notice, this 00012 * list of conditions and the following disclaimer in the documentation and/or 00013 * other materials provided with the distribution. 00014 * 00015 * 3. Neither the name of Nordic Semiconductor ASA nor the names of other 00016 * contributors to this software may be used to endorse or promote products 00017 * derived from this software without specific prior written permission. 00018 * 00019 * 00020 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND 00021 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED 00022 * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE 00023 * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR 00024 * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES 00025 * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; 00026 * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON 00027 * ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 00028 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS 00029 * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 00030 * 00031 */ 00032 00033 #include "app_scheduler.h " 00034 #include <stdlib.h> 00035 #include <stdint.h> 00036 #include <string.h> 00037 #include "nrf_soc.h" 00038 #include "nrf_assert.h" 00039 #include "app_util.h " 00040 #include "app_util_platform.h " 00041 00042 /**@brief Structure for holding a scheduled event header. */ 00043 typedef struct 00044 { 00045 app_sched_event_handler_t handler; /**< Pointer to event handler to receive the event. */ 00046 uint16_t event_data_size; /**< Size of event data. */ 00047 } event_header_t; 00048 00049 STATIC_ASSERT(sizeof(event_header_t) <= APP_SCHED_EVENT_HEADER_SIZE); 00050 00051 static event_header_t * m_queue_event_headers; /**< Array for holding the queue event headers. */ 00052 static uint8_t * m_queue_event_data; /**< Array for holding the queue event data. */ 00053 static volatile uint8_t m_queue_start_index; /**< Index of queue entry at the start of the queue. */ 00054 static volatile uint8_t m_queue_end_index; /**< Index of queue entry at the end of the queue. */ 00055 static uint16_t m_queue_event_size; /**< Maximum event size in queue. */ 00056 static uint16_t m_queue_size; /**< Number of queue entries. */ 00057 00058 /**@brief Function for incrementing a queue index, and handle wrap-around. 00059 * 00060 * @param[in] index Old index. 00061 * 00062 * @return New (incremented) index. 00063 */ 00064 static __INLINE uint8_t next_index(uint8_t index) 00065 { 00066 return (index < m_queue_size) ? (index + 1) : 0; 00067 } 00068 00069 00070 static __INLINE uint8_t app_sched_queue_full() 00071 { 00072 uint8_t tmp = m_queue_start_index; 00073 return next_index(m_queue_end_index) == tmp; 00074 } 00075 00076 /**@brief Macro for checking if a queue is full. */ 00077 #define APP_SCHED_QUEUE_FULL() app_sched_queue_full() 00078 00079 00080 static __INLINE uint8_t app_sched_queue_empty() 00081 { 00082 uint8_t tmp = m_queue_start_index; 00083 return m_queue_end_index == tmp; 00084 } 00085 00086 /**@brief Macro for checking if a queue is empty. */ 00087 #define APP_SCHED_QUEUE_EMPTY() app_sched_queue_empty() 00088 00089 00090 uint32_t app_sched_init(uint16_t event_size, uint16_t queue_size, void * p_event_buffer) 00091 { 00092 uint16_t data_start_index = (queue_size + 1) * sizeof(event_header_t); 00093 00094 // Check that buffer is correctly aligned 00095 if (!is_word_aligned(p_event_buffer)) 00096 { 00097 return NRF_ERROR_INVALID_PARAM; 00098 } 00099 00100 // Initialize event scheduler 00101 m_queue_event_headers = p_event_buffer; 00102 m_queue_event_data = &((uint8_t *)p_event_buffer)[data_start_index]; 00103 m_queue_end_index = 0; 00104 m_queue_start_index = 0; 00105 m_queue_event_size = event_size; 00106 m_queue_size = queue_size; 00107 00108 return NRF_SUCCESS; 00109 } 00110 00111 00112 uint32_t app_sched_event_put(void * p_event_data, 00113 uint16_t event_data_size, 00114 app_sched_event_handler_t handler) 00115 { 00116 uint32_t err_code; 00117 00118 if (event_data_size <= m_queue_event_size) 00119 { 00120 uint16_t event_index = 0xFFFF; 00121 00122 CRITICAL_REGION_ENTER(); 00123 00124 if (!APP_SCHED_QUEUE_FULL()) 00125 { 00126 event_index = m_queue_end_index; 00127 m_queue_end_index = next_index(m_queue_end_index); 00128 } 00129 00130 CRITICAL_REGION_EXIT(); 00131 00132 if (event_index != 0xFFFF) 00133 { 00134 // NOTE: This can be done outside the critical region since the event consumer will 00135 // always be called from the main loop, and will thus never interrupt this code. 00136 m_queue_event_headers[event_index].handler = handler; 00137 if ((p_event_data != NULL) && (event_data_size > 0)) 00138 { 00139 memcpy(&m_queue_event_data[event_index * m_queue_event_size], 00140 p_event_data, 00141 event_data_size); 00142 m_queue_event_headers[event_index].event_data_size = event_data_size; 00143 } 00144 else 00145 { 00146 m_queue_event_headers[event_index].event_data_size = 0; 00147 } 00148 00149 err_code = NRF_SUCCESS; 00150 } 00151 else 00152 { 00153 err_code = NRF_ERROR_NO_MEM; 00154 } 00155 } 00156 else 00157 { 00158 err_code = NRF_ERROR_INVALID_LENGTH; 00159 } 00160 00161 return err_code; 00162 } 00163 00164 00165 /**@brief Function for reading the next event from specified event queue. 00166 * 00167 * @param[out] pp_event_data Pointer to pointer to event data. 00168 * @param[out] p_event_data_size Pointer to size of event data. 00169 * @param[out] p_event_handler Pointer to event handler function pointer. 00170 * 00171 * @return NRF_SUCCESS if new event, NRF_ERROR_NOT_FOUND if event queue is empty. 00172 */ 00173 static uint32_t app_sched_event_get(void ** pp_event_data, 00174 uint16_t * p_event_data_size, 00175 app_sched_event_handler_t * p_event_handler) 00176 { 00177 uint32_t err_code = NRF_ERROR_NOT_FOUND; 00178 00179 if (!APP_SCHED_QUEUE_EMPTY()) 00180 { 00181 uint16_t event_index; 00182 00183 // NOTE: There is no need for a critical region here, as this function will only be called 00184 // from app_sched_execute() from inside the main loop, so it will never interrupt 00185 // app_sched_event_put(). Also, updating of (i.e. writing to) the start index will be 00186 // an atomic operation. 00187 event_index = m_queue_start_index; 00188 m_queue_start_index = next_index(m_queue_start_index); 00189 00190 *pp_event_data = &m_queue_event_data[event_index * m_queue_event_size]; 00191 *p_event_data_size = m_queue_event_headers[event_index].event_data_size; 00192 *p_event_handler = m_queue_event_headers[event_index].handler; 00193 00194 err_code = NRF_SUCCESS; 00195 } 00196 00197 return err_code; 00198 } 00199 00200 00201 void app_sched_execute(void) 00202 { 00203 void * p_event_data; 00204 uint16_t event_data_size; 00205 app_sched_event_handler_t event_handler; 00206 00207 // Get next event (if any), and execute handler 00208 while ((app_sched_event_get(&p_event_data, &event_data_size, &event_handler) == NRF_SUCCESS)) 00209 { 00210 event_handler(p_event_data, event_data_size); 00211 } 00212 }
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