#pragma once #include "AP_HAL_Namespace.h" #include #define HAL_SEMAPHORE_BLOCK_FOREVER 0 class AP_HAL::Semaphore { public: Semaphore() {} // do not allow copying CLASS_NO_COPY(Semaphore); virtual bool take(uint32_t timeout_ms) WARN_IF_UNUSED = 0 ; virtual bool take_nonblocking() WARN_IF_UNUSED = 0; // a variant that blocks forever #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wunused-result" virtual void take_blocking() { take(HAL_SEMAPHORE_BLOCK_FOREVER); }; #pragma GCC diagnostic pop virtual bool give() = 0; virtual ~Semaphore(void) {} }; /* a method to make semaphores less error prone. The WITH_SEMAPHORE() macro will block forever for a semaphore, and will automatically release the semaphore when it goes out of scope Note that we have two types of semaphores. A normal semaphore can only be taken once. A recursive semaphore allows for the thread holding the semaphore to take it again. It must be released the same number of times it is taken. The WITH_SEMAPHORE() macro can be used with either type of semaphore */ class WithSemaphore { public: WithSemaphore(AP_HAL::Semaphore *mtx, uint32_t line); WithSemaphore(AP_HAL::Semaphore &mtx, uint32_t line); ~WithSemaphore(); private: AP_HAL::Semaphore &_mtx; }; // From: https://stackoverflow.com/questions/19666142/why-is-a-level-of-indirection-needed-for-this-concatenation-macro #define WITH_SEMAPHORE( sem ) JOIN( sem, __AP_LINE__, __COUNTER__ ) #define JOIN( sem, line, counter ) _DO_JOIN( sem, line, counter ) #define _DO_JOIN( sem, line, counter ) WithSemaphore _getsem ## counter(sem, line) /* a binary semaphore */ class AP_HAL::BinarySemaphore { public: /* create a binary semaphore. initial_state determines if a wait() immediately after creation would block. If initial_state is true then it won't block, if initial_state is false it will block */ BinarySemaphore(bool initial_state=false) {} // do not allow copying CLASS_NO_COPY(BinarySemaphore); virtual bool wait(uint32_t timeout_us) WARN_IF_UNUSED = 0 ; virtual bool wait_blocking() = 0; virtual bool wait_nonblocking() { return wait(0); } virtual void signal() = 0; virtual void signal_ISR() { signal(); } virtual ~BinarySemaphore(void) {} };