X-Git-Url: http://git.cascardo.eti.br/?a=blobdiff_plain;f=lib%2Fovs-thread.h;h=55e51a4ed5e672780dcf284ab770d349b4076e4c;hb=HEAD;hp=a3e2696a8670a6ce569a9e7c4dbfdc7ef386ca8b;hpb=ed27e010b9ae9f3605c56a7e3580660efce65c98;p=cascardo%2Fovs.git diff --git a/lib/ovs-thread.h b/lib/ovs-thread.h index a3e2696a8..55e51a4ed 100644 --- a/lib/ovs-thread.h +++ b/lib/ovs-thread.h @@ -1,5 +1,5 @@ /* - * Copyright (c) 2013 Nicira, Inc. + * Copyright (c) 2013, 2014 Nicira, Inc. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. @@ -21,43 +21,18 @@ #include #include #include "ovs-atomic.h" +#include "openvswitch/thread.h" #include "util.h" +struct seq; -/* Mutex. */ -struct OVS_LOCKABLE ovs_mutex { - pthread_mutex_t lock; - const char *where; +/* Poll-block()-able barrier similar to pthread_barrier_t. */ +struct ovs_barrier { + uint32_t size; /* Number of threads to wait. */ + atomic_count count; /* Number of threads already hit the barrier. */ + struct seq *seq; }; -/* "struct ovs_mutex" initializer. */ -#ifdef PTHREAD_ERRORCHECK_MUTEX_INITIALIZER_NP -#define OVS_MUTEX_INITIALIZER { PTHREAD_ERRORCHECK_MUTEX_INITIALIZER_NP, NULL } -#else -#define OVS_MUTEX_INITIALIZER { PTHREAD_MUTEX_INITIALIZER, NULL } -#endif - -/* ovs_mutex functions analogous to pthread_mutex_*() functions. - * - * Most of these functions abort the process with an error message on any - * error. ovs_mutex_trylock() is an exception: it passes through a 0 or EBUSY - * return value to the caller and aborts on any other error. */ -void ovs_mutex_init(const struct ovs_mutex *); -void ovs_mutex_init_recursive(const struct ovs_mutex *); -void ovs_mutex_destroy(const struct ovs_mutex *); -void ovs_mutex_unlock(const struct ovs_mutex *mutex) OVS_RELEASES(mutex); -void ovs_mutex_lock_at(const struct ovs_mutex *mutex, const char *where) - OVS_ACQUIRES(mutex); -#define ovs_mutex_lock(mutex) \ - ovs_mutex_lock_at(mutex, SOURCE_LOCATOR) - -int ovs_mutex_trylock_at(const struct ovs_mutex *mutex, const char *where) - OVS_TRY_LOCK(0, mutex); -#define ovs_mutex_trylock(mutex) \ - ovs_mutex_trylock_at(mutex, SOURCE_LOCATOR) - -void ovs_mutex_cond_wait(pthread_cond_t *, const struct ovs_mutex *); - /* Wrappers for pthread_mutex_*() that abort the process on any error. * This is still needed when ovs-atomic-pthreads.h is used. */ void xpthread_mutex_lock(pthread_mutex_t *mutex); @@ -69,14 +44,30 @@ void xpthread_mutexattr_destroy(pthread_mutexattr_t *); void xpthread_mutexattr_settype(pthread_mutexattr_t *, int type); void xpthread_mutexattr_gettype(pthread_mutexattr_t *, int *typep); -/* Read-write lock. */ +/* Read-write lock. + * + * An ovs_rwlock does not support recursive readers, because POSIX allows + * taking the reader lock recursively to deadlock when a thread is waiting on + * the write-lock. (NetBSD does deadlock.) glibc rwlocks in their default + * configuration do not deadlock, but ovs_rwlock_init() initializes rwlocks as + * non-recursive (which will deadlock) for two reasons: + * + * - glibc only provides fairness to writers in this mode. + * + * - It's better to find bugs in the primary Open vSwitch target rather + * than exposing them only to porters. */ struct OVS_LOCKABLE ovs_rwlock { pthread_rwlock_t lock; - const char *where; + const char *where; /* NULL if and only if uninitialized. */ }; /* Initializer. */ -#define OVS_RWLOCK_INITIALIZER { PTHREAD_RWLOCK_INITIALIZER, NULL } +#ifdef PTHREAD_RWLOCK_WRITER_NONRECURSIVE_INITIALIZER_NP +#define OVS_RWLOCK_INITIALIZER \ + { PTHREAD_RWLOCK_WRITER_NONRECURSIVE_INITIALIZER_NP, "" } +#else +#define OVS_RWLOCK_INITIALIZER { PTHREAD_RWLOCK_INITIALIZER, "" } +#endif /* ovs_rwlock functions analogous to pthread_rwlock_*() functions. * @@ -87,25 +78,37 @@ void ovs_rwlock_init(const struct ovs_rwlock *); void ovs_rwlock_destroy(const struct ovs_rwlock *); void ovs_rwlock_unlock(const struct ovs_rwlock *rwlock) OVS_RELEASES(rwlock); +/* Wrappers for pthread_rwlockattr_*() that abort the process on any error. */ +void xpthread_rwlockattr_init(pthread_rwlockattr_t *); +void xpthread_rwlockattr_destroy(pthread_rwlockattr_t *); +#ifdef PTHREAD_RWLOCK_WRITER_NONRECURSIVE_INITIALIZER_NP +void xpthread_rwlockattr_setkind_np(pthread_rwlockattr_t *, int kind); +#endif + void ovs_rwlock_wrlock_at(const struct ovs_rwlock *rwlock, const char *where) OVS_ACQ_WRLOCK(rwlock); #define ovs_rwlock_wrlock(rwlock) \ - ovs_rwlock_wrlock_at(rwlock, SOURCE_LOCATOR) + ovs_rwlock_wrlock_at(rwlock, OVS_SOURCE_LOCATOR) int ovs_rwlock_trywrlock_at(const struct ovs_rwlock *rwlock, const char *where) OVS_TRY_WRLOCK(0, rwlock); #define ovs_rwlock_trywrlock(rwlock) \ - ovs_rwlock_trywrlock_at(rwlock, SOURCE_LOCATOR) + ovs_rwlock_trywrlock_at(rwlock, OVS_SOURCE_LOCATOR) void ovs_rwlock_rdlock_at(const struct ovs_rwlock *rwlock, const char *where) OVS_ACQ_RDLOCK(rwlock); #define ovs_rwlock_rdlock(rwlock) \ - ovs_rwlock_rdlock_at(rwlock, SOURCE_LOCATOR) + ovs_rwlock_rdlock_at(rwlock, OVS_SOURCE_LOCATOR) int ovs_rwlock_tryrdlock_at(const struct ovs_rwlock *rwlock, const char *where) OVS_TRY_RDLOCK(0, rwlock); #define ovs_rwlock_tryrdlock(rwlock) \ - ovs_rwlock_tryrdlock_at(rwlock, SOURCE_LOCATOR) + ovs_rwlock_tryrdlock_at(rwlock, OVS_SOURCE_LOCATOR) + +/* ovs_barrier functions analogous to pthread_barrier_*() functions. */ +void ovs_barrier_init(struct ovs_barrier *, uint32_t count); +void ovs_barrier_destroy(struct ovs_barrier *); +void ovs_barrier_block(struct ovs_barrier *); /* Wrappers for xpthread_cond_*() that abort the process on any error. * @@ -115,33 +118,34 @@ void xpthread_cond_destroy(pthread_cond_t *); void xpthread_cond_signal(pthread_cond_t *); void xpthread_cond_broadcast(pthread_cond_t *); -#ifdef __CHECKER__ -/* Replace these functions by the macros already defined in the - * annotations, because the macro definitions have correct semantics for the - * conditional acquisition that can't be captured in a function annotation. - * The difference in semantics from pthread_*() to xpthread_*() does not matter - * because sparse is not a compiler. */ -#define xpthread_mutex_trylock pthread_mutex_trylock -#define xpthread_rwlock_tryrdlock pthread_rwlock_tryrdlock -#define xpthread_rwlock_trywrlock pthread_rwlock_trywrlock -#endif - void xpthread_key_create(pthread_key_t *, void (*destructor)(void *)); +void xpthread_key_delete(pthread_key_t); void xpthread_setspecific(pthread_key_t, const void *); -void xpthread_create(pthread_t *, pthread_attr_t *, void *(*)(void *), void *); +#ifndef _WIN32 +void xpthread_sigmask(int, const sigset_t *, sigset_t *); +#endif + +pthread_t ovs_thread_create(const char *name, void *(*)(void *), void *); void xpthread_join(pthread_t, void **); /* Per-thread data. * - * Multiple forms of per-thread data exist, each with its own pluses and - * minuses: + * + * Standard Forms + * ============== + * + * Multiple forms of standard per-thread data exist, each with its own pluses + * and minuses. In general, if one of these forms is appropriate, then it's a + * good idea to use it: * * - POSIX per-thread data via pthread_key_t is portable to any pthreads * implementation, and allows a destructor function to be defined. It * only (directly) supports per-thread pointers, which are always * initialized to NULL. It requires once-only allocation of a - * pthread_key_t value. It is relatively slow. + * pthread_key_t value. It is relatively slow. Typically few + * "pthread_key_t"s are available (POSIX requires only at least 128, + * glibc supplies only 1024). * * - The thread_local feature newly defined in C11 works with * any data type and initializer, and it is fast. thread_local does not @@ -149,7 +153,8 @@ void xpthread_join(pthread_t, void **); * define what happens if one attempts to access a thread_local object * from a thread other than the one to which that object belongs. There * is no provision to call a user-specified destructor when a thread - * ends. + * ends. Typical implementations allow for an arbitrary amount of + * thread_local storage, but statically allocated only. * * - The __thread keyword is a GCC extension similar to thread_local but * with a longer history. __thread is not portable to every GCC version @@ -166,6 +171,25 @@ void xpthread_join(pthread_t, void **); * needs key allocation? yes no no * arbitrary initializer? no yes yes * cross-thread access? yes no yes + * amount available? few arbitrary arbitrary + * dynamically allocated? yes no no + * + * + * Extensions + * ========== + * + * OVS provides some extensions and wrappers: + * + * - In a situation where the performance of thread_local or __thread is + * desirable, but portability is required, DEFINE_STATIC_PER_THREAD_DATA + * and DECLARE_EXTERN_PER_THREAD_DATA/DEFINE_EXTERN_PER_THREAD_DATA may + * be appropriate (see below). + * + * - DEFINE_PER_THREAD_MALLOCED_DATA can be convenient for simple + * per-thread malloc()'d buffers. + * + * - struct ovs_tsd provides an alternative to pthread_key_t that isn't + * limited to a small number of keys. */ /* For static data, use this macro in a source file: @@ -402,80 +426,37 @@ void xpthread_join(pthread_t, void **); NAME##_init(); \ return NAME##_set_unsafe(value); \ } - -/* Convenient once-only execution. - * - * - * Problem - * ======= - * - * POSIX provides pthread_once_t and pthread_once() as primitives for running a - * set of code only once per process execution. They are used like this: - * - * static void run_once(void) { ...initialization... } - * static pthread_once_t once = PTHREAD_ONCE_INIT; - * ... - * pthread_once(&once, run_once); - * - * pthread_once() does not allow passing any parameters to the initialization - * function, which is often inconvenient, because it means that the function - * can only access data declared at file scope. + +/* Dynamically allocated thread-specific data with lots of slots. * + * pthread_key_t can provide as few as 128 pieces of thread-specific data (even + * glibc is limited to 1,024). Thus, one must be careful to allocate only a + * few keys globally. One cannot, for example, allocate a key for every + * instance of a data structure if there might be an arbitrary number of those + * data structures. * - * Solution - * ======== + * This API is similar to the pthread one (simply search and replace pthread_ + * by ovsthread_) but it a much larger limit that can be raised if necessary + * (by recompiling). Thus, one may more freely use this form of + * thread-specific data. * - * Use ovsthread_once, like this, instead: + * ovsthread_key_t also differs from pthread_key_t in the following ways: * - * static struct ovsthread_once once = OVSTHREAD_ONCE_INITIALIZER; + * - Destructors must not access thread-specific data (via ovsthread_key). * - * if (ovsthread_once_start(&once)) { - * ...initialization... - * ovsthread_once_done(&once); - * } + * - The pthread_key_t API allows concurrently exiting threads to start + * executing the destructor after pthread_key_delete() returns. The + * ovsthread_key_t API guarantees that, when ovsthread_key_delete() + * returns, all destructors have returned and no new ones will start + * execution. */ +typedef struct ovsthread_key *ovsthread_key_t; -struct ovsthread_once { - atomic_bool done; - struct ovs_mutex mutex; -}; - -#define OVSTHREAD_ONCE_INITIALIZER \ - { \ - ATOMIC_VAR_INIT(false), \ - OVS_MUTEX_INITIALIZER, \ - } - -static inline bool ovsthread_once_start(struct ovsthread_once *once) - OVS_TRY_LOCK(true, once->mutex); -void ovsthread_once_done(struct ovsthread_once *once) - OVS_RELEASES(once->mutex); - -bool ovsthread_once_start__(struct ovsthread_once *once) - OVS_TRY_LOCK(false, once->mutex); - -static inline bool -ovsthread_once_is_done__(struct ovsthread_once *once) -{ - bool done; - - atomic_read_explicit(&once->done, &done, memory_order_relaxed); - return done; -} +void ovsthread_key_create(ovsthread_key_t *, void (*destructor)(void *)); +void ovsthread_key_delete(ovsthread_key_t); -/* Returns true if this is the first call to ovsthread_once_start() for - * 'once'. In this case, the caller should perform whatever initialization - * actions it needs to do, then call ovsthread_once_done() for 'once'. - * - * Returns false if this is not the first call to ovsthread_once_start() for - * 'once'. In this case, the call will not return until after - * ovsthread_once_done() has been called. */ -static inline bool -ovsthread_once_start(struct ovsthread_once *once) -{ - return OVS_UNLIKELY(!ovsthread_once_is_done__(once) - && !ovsthread_once_start__(once)); -} +void ovsthread_setspecific(ovsthread_key_t, const void *); +void *ovsthread_getspecific(ovsthread_key_t); /* Thread ID. * @@ -507,17 +488,34 @@ ovsthread_id_self(void) * * Fully thread-safe. */ -struct ovsthread_counter *ovsthread_counter_create(void); -void ovsthread_counter_destroy(struct ovsthread_counter *); -void ovsthread_counter_inc(struct ovsthread_counter *, unsigned long long int); -unsigned long long int ovsthread_counter_read( - const struct ovsthread_counter *); +struct ovsthread_stats { + struct ovs_mutex mutex; + void *volatile buckets[16]; +}; + +void ovsthread_stats_init(struct ovsthread_stats *); +void ovsthread_stats_destroy(struct ovsthread_stats *); + +void *ovsthread_stats_bucket_get(struct ovsthread_stats *, + void *(*new_bucket)(void)); + +#define OVSTHREAD_STATS_FOR_EACH_BUCKET(BUCKET, IDX, STATS) \ + for ((IDX) = ovs_thread_stats_next_bucket(STATS, 0); \ + ((IDX) < ARRAY_SIZE((STATS)->buckets) \ + ? ((BUCKET) = (STATS)->buckets[IDX], true) \ + : false); \ + (IDX) = ovs_thread_stats_next_bucket(STATS, (IDX) + 1)) +size_t ovs_thread_stats_next_bucket(const struct ovsthread_stats *, size_t); +bool single_threaded(void); + void assert_single_threaded_at(const char *where); -#define assert_single_threaded() assert_single_threaded_at(SOURCE_LOCATOR) +#define assert_single_threaded() assert_single_threaded_at(OVS_SOURCE_LOCATOR) +#ifndef _WIN32 pid_t xfork_at(const char *where); -#define xfork() xfork_at(SOURCE_LOCATOR) +#define xfork() xfork_at(OVS_SOURCE_LOCATOR) +#endif void forbid_forking(const char *reason); bool may_fork(void); @@ -525,5 +523,6 @@ bool may_fork(void); /* Useful functions related to threading. */ int count_cpu_cores(void); +bool thread_is_pmd(void); #endif /* ovs-thread.h */