================== OS Data Structures ================== Scalar Types ============ Many of the types used to communicate with NuttX are simple scalar types. These types are used to provide architecture independence of the OS from the application. The scalar types used at the NuttX interface include: .. c:type:: pid_t .. c:type:: size_t .. c:type:: sigset_t .. c:type:: time_t Hidden Interface Structures =========================== Several of the types used to interface with NuttX are structures that are intended to be hidden from the application. From the standpoint of the application, these structures (and structure pointers) should be treated as simple handles to reference OS resources. These hidden structures include: .. c:struct:: tcb_s .. c:type:: mqd_t .. c:type:: sem_t .. c:type:: pthread_key_t In order to maintain portability, applications should not reference specific elements within these hidden structures. These hidden structures will not be described further in this user's manual. Access to the ``errno`` Variable ================================ A pointer to the thread-specific ``errno`` value is available through a function call: .. c:function:: int *__errno(void) ``__errno()`` returns a pointer to the thread-specific ``errno`` value. Note that the symbol ``errno`` is defined to be ``__errno()`` so that the usual access by referencing the symbol ``errno`` will work as expected. .. code-block:: c #include #define errno *__errno() int *__errno(void); There is a unique, private ``errno`` value for each NuttX task. However, the implementation of ``errno`` differs somewhat from the use of ``errno`` in most multi-threaded process environments: In NuttX, each pthread will also have its own private copy of ``errno`` and the ``errno`` will not be shared between pthreads. This is, perhaps, non-standard but promotes better thread independence. :return: A pointer to the thread-specific ``errno`` value. User Interface Structures ========================= .. c:type:: int (*main_t)(int argc, char *argv[]) :c:type:`main_t` defines the type of a task entry point. :c:type:`main_t` is declared in ``sys/types.h``. .. c:struct:: sched_param This structure is used to pass scheduling priorities to and from NuttX: .. code-block:: c struct sched_param { int sched_priority; }; .. c:struct:: timespec This structure is used to pass timing information between the NuttX and a user application: .. code-block:: c struct timespec { time_t tv_sec; /* Seconds */ long tv_nsec; /* Nanoseconds */ }; .. c:struct:: mq_attr This structure is used to communicate message queue attributes between NuttX and a MoBY application: .. code-block:: c struct mq_attr { size_t mq_maxmsg; /* Max number of messages in queue */ size_t mq_msgsize; /* Max message size */ unsigned mq_flags; /* Queue flags */ size_t mq_curmsgs; /* Number of messages currently in queue */ }; .. note that this gives a warning due to https://github.com/sphinx-doc/sphinx/issues/7819 https://github.com/sphinx-doc/sphinx/pull/8313 .. c:struct:: sigaction The following structure defines the action to take for given signal: .. code-block:: c struct sigaction { union { void (*_sa_handler)(int); void (*_sa_sigaction)(int, siginfo_t *, void *); } sa_u; sigset_t sa_mask; int sa_flags; }; #define sa_handler sa_u._sa_handler #define sa_sigaction sa_u._sa_sigaction .. c:struct:: siginfo .. c:type:: siginfo_t The following types is used to pass parameters to/from signal handlers: .. code-block:: c typedef struct siginfo { int si_signo; int si_code; union sigval si_value; } siginfo_t; .. c:union:: sigval This defines the type of the struct siginfo si_value field and is used to pass parameters with signals. .. code-block:: c union sigval { int sival_int; void *sival_ptr; }; .. c:struct:: sigevent The following is used to attach a signal to a message queue to notify a task when a message is available on a queue. .. code-block:: c struct sigevent { int sigev_signo; union sigval sigev_value; int sigev_notify; };