5.2.1 - Updated I2C files
Dependents: mbed-TFT-example-NCS36510 mbed-Accelerometer-example-NCS36510 mbed-Accelerometer-example-NCS36510
events/equeue/equeue_platform.h
- Committer:
- group-onsemi
- Date:
- 2017-01-25
- Revision:
- 0:098463de4c5d
File content as of revision 0:098463de4c5d:
/** \addtogroup events */ /** @{*/ /* * System specific implementation * * Copyright (c) 2016 Christopher Haster * * 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. */ #ifndef EQUEUE_PLATFORM_H #define EQUEUE_PLATFORM_H #ifdef __cplusplus extern "C" { #endif #include <stdbool.h> // Currently supported platforms // // Uncomment to select a supported platform or reimplement this file // for a specific target. //#define EQUEUE_PLATFORM_POSIX //#define EQUEUE_PLATFORM_MBED // Try to infer a platform if none was manually selected #if !defined(EQUEUE_PLATFORM_POSIX) \ && !defined(EQUEUE_PLATFORM_MBED) #if defined(__unix__) #define EQUEUE_PLATFORM_POSIX #elif defined(__MBED__) #define EQUEUE_PLATFORM_MBED #else #warning "Unknown platform! Please update equeue_platform.h" #endif #endif // Platform includes #if defined(EQUEUE_PLATFORM_POSIX) #include <pthread.h> #endif // Platform millisecond counter // // Return a tick that represents the number of milliseconds that have passed // since an arbitrary point in time. The granularity does not need to be at // the millisecond level, however the accuracy of the equeue library is // limited by the accuracy of this tick. // // Must intentionally overflow to 0 after 2^32-1 unsigned equeue_tick(void); // Platform mutex type // // The equeue library requires at minimum a non-recursive mutex that is // safe in interrupt contexts. The mutex section is help for a bounded // amount of time, so simply disabling interrupts is acceptable // // If irq safety is not required, a regular blocking mutex can be used. #if defined(EQUEUE_PLATFORM_POSIX) typedef pthread_mutex_t equeue_mutex_t; #elif defined(EQUEUE_PLATFORM_WINDOWS) typedef CRITICAL_SECTION equeue_mutex_t; #elif defined(EQUEUE_PLATFORM_MBED) typedef unsigned equeue_mutex_t; #elif defined(EQUEUE_PLATFORM_FREERTOS) typedef UBaseType_t equeue_mutex_t; #endif // Platform mutex operations // // The equeue_mutex_create and equeue_mutex_destroy manage the lifetime // of the mutex. On error, equeue_mutex_create should return a negative // error code. // // The equeue_mutex_lock and equeue_mutex_unlock lock and unlock the // underlying mutex. int equeue_mutex_create(equeue_mutex_t *mutex); void equeue_mutex_destroy(equeue_mutex_t *mutex); void equeue_mutex_lock(equeue_mutex_t *mutex); void equeue_mutex_unlock(equeue_mutex_t *mutex); // Platform semaphore type // // The equeue library requires a binary semaphore type that can be safely // signaled from interrupt contexts and from inside a equeue_mutex section. // // The equeue_signal_wait is relied upon by the equeue library to sleep the // processor between events. Spurious wakeups have no negative-effects. // // A counting semaphore will also work, however may cause the event queue // dispatch loop to run unnecessarily. For that matter, equeue_signal_wait // may even be implemented as a single return statement. #if defined(EQUEUE_PLATFORM_POSIX) typedef struct equeue_sema { pthread_mutex_t mutex; pthread_cond_t cond; bool signal; } equeue_sema_t; #elif defined(EQUEUE_PLATFORM_MBED) && defined(MBED_CONF_RTOS_PRESENT) typedef unsigned equeue_sema_t[8]; #elif defined(EQUEUE_PLATFORM_MBED) typedef volatile int equeue_sema_t; #endif // Platform semaphore operations // // The equeue_sema_create and equeue_sema_destroy manage the lifetime // of the semaphore. On error, equeue_sema_create should return a negative // error code. // // The equeue_sema_signal marks a semaphore as signalled such that the next // equeue_sema_wait will return true. // // The equeue_sema_wait waits for a semaphore to be signalled or returns // immediately if equeue_sema_signal had been called since the last // equeue_sema_wait. The equeue_sema_wait returns true if it detected that // equeue_sema_signal had been called. int equeue_sema_create(equeue_sema_t *sema); void equeue_sema_destroy(equeue_sema_t *sema); void equeue_sema_signal(equeue_sema_t *sema); bool equeue_sema_wait(equeue_sema_t *sema, int ms); #ifdef __cplusplus } #endif #endif /** @}*/