/* * QEMU aio implementation * * Copyright IBM, Corp. 2008 * * Authors: * Anthony Liguori <aliguori@us.ibm.com> * * This work is licensed under the terms of the GNU GPL, version 2. See * the COPYING file in the top-level directory. * * Contributions after 2012-01-13 are licensed under the terms of the * GNU GPL, version 2 or (at your option) any later version. */ #include "qemu/osdep.h" #include "qemu-common.h" #include "block/block.h" #include "qemu/queue.h" #include "qemu/sockets.h" #ifdef CONFIG_EPOLL_CREATE1 #include <sys/epoll.h> #endif struct AioHandler { GPollFD pfd; IOHandler *io_read; IOHandler *io_write; int deleted; void *opaque; bool is_external; QLIST_ENTRY(AioHandler) node; }; #ifdef CONFIG_EPOLL_CREATE1 /* The fd number threashold to switch to epoll */ #define EPOLL_ENABLE_THRESHOLD 64 static void aio_epoll_disable(AioContext *ctx) { ctx->epoll_available = false; if (!ctx->epoll_enabled) { return; } ctx->epoll_enabled = false; close(ctx->epollfd); } static inline int epoll_events_from_pfd(int pfd_events) { return (pfd_events & G_IO_IN ? EPOLLIN : 0) | (pfd_events & G_IO_OUT ? EPOLLOUT : 0) | (pfd_events & G_IO_HUP ? EPOLLHUP : 0) | (pfd_events & G_IO_ERR ? EPOLLERR : 0); } static bool aio_epoll_try_enable(AioContext *ctx) { AioHandler *node; struct epoll_event event; QLIST_FOREACH(node, &ctx->aio_handlers, node) { int r; if (node->deleted || !node->pfd.events) { continue; } event.events = epoll_events_from_pfd(node->pfd.events); event.data.ptr = node; r = epoll_ctl(ctx->epollfd, EPOLL_CTL_ADD, node->pfd.fd, &event); if (r) { return false; } } ctx->epoll_enabled = true; return true; } static void aio_epoll_update(AioContext *ctx, AioHandler *node, bool is_new) { struct epoll_event event; int r; if (!ctx->epoll_enabled) { return; } if (!node->pfd.events) { r = epoll_ctl(ctx->epollfd, EPOLL_CTL_DEL, node->pfd.fd, &event); if (r) { aio_epoll_disable(ctx); } } else { event.data.ptr = node; event.events = epoll_events_from_pfd(node->pfd.events); if (is_new) { r = epoll_ctl(ctx->epollfd, EPOLL_CTL_ADD, node->pfd.fd, &event); if (r) { aio_epoll_disable(ctx); } } else { r = epoll_ctl(ctx->epollfd, EPOLL_CTL_MOD, node->pfd.fd, &event); if (r) { aio_epoll_disable(ctx); } } } } static int aio_epoll(AioContext *ctx, GPollFD *pfds, unsigned npfd, int64_t timeout) { AioHandler *node; int i, ret = 0; struct epoll_event events[128]; assert(npfd == 1); assert(pfds[0].fd == ctx->epollfd); if (timeout > 0) { ret = qemu_poll_ns(pfds, npfd, timeout); } if (timeout <= 0 || ret > 0) { ret = epoll_wait(ctx->epollfd, events, sizeof(events) / sizeof(events[0]), timeout); if (ret <= 0) { goto out; } for (i = 0; i < ret; i++) { int ev = events[i].events; node = events[i].data.ptr; node->pfd.revents = (ev & EPOLLIN ? G_IO_IN : 0) | (ev & EPOLLOUT ? G_IO_OUT : 0) | (ev & EPOLLHUP ? G_IO_HUP : 0) | (ev & EPOLLERR ? G_IO_ERR : 0); } } out: return ret; } static bool aio_epoll_enabled(AioContext *ctx) { /* Fall back to ppoll when external clients are disabled. */ return !aio_external_disabled(ctx) && ctx->epoll_enabled; } static bool aio_epoll_check_poll(AioContext *ctx, GPollFD *pfds, unsigned npfd, int64_t timeout) { if (!ctx->epoll_available) { return false; } if (aio_epoll_enabled(ctx)) { return true; } if (npfd >= EPOLL_ENABLE_THRESHOLD) { if (aio_epoll_try_enable(ctx)) { return true; } else { aio_epoll_disable(ctx); } } return false; } #else static void aio_epoll_update(AioContext *ctx, AioHandler *node, bool is_new) { } static int aio_epoll(AioContext *ctx, GPollFD *pfds, unsigned npfd, int64_t timeout) { assert(false); } static bool aio_epoll_enabled(AioContext *ctx) { return false; } static bool aio_epoll_check_poll(AioContext *ctx, GPollFD *pfds, unsigned npfd, int64_t timeout) { return false; } #endif static AioHandler *find_aio_handler(AioContext *ctx, int fd) { AioHandler *node; QLIST_FOREACH(node, &ctx->aio_handlers, node) { if (node->pfd.fd == fd) if (!node->deleted) return node; } return NULL; } void aio_set_fd_handler(AioContext *ctx, int fd, bool is_external, IOHandler *io_read, IOHandler *io_write, void *opaque) { AioHandler *node; bool is_new = false; bool deleted = false; node = find_aio_handler(ctx, fd); /* Are we deleting the fd handler? */ if (!io_read && !io_write) { if (node) { g_source_remove_poll(&ctx->source, &node->pfd); /* If the lock is held, just mark the node as deleted */ if (ctx->walking_handlers) { node->deleted = 1; node->pfd.revents = 0; } else { /* Otherwise, delete it for real. We can't just mark it as * deleted because deleted nodes are only cleaned up after * releasing the walking_handlers lock. */ QLIST_REMOVE(node, node); deleted = true; } } } else { if (node == NULL) { /* Alloc and insert if it's not already there */ node = g_new0(AioHandler, 1); node->pfd.fd = fd; QLIST_INSERT_HEAD(&ctx->aio_handlers, node, node); g_source_add_poll(&ctx->source, &node->pfd); is_new = true; } /* Update handler with latest information */ node->io_read = io_read; node->io_write = io_write; node->opaque = opaque; node->is_external = is_external; node->pfd.events = (io_read ? G_IO_IN | G_IO_HUP | G_IO_ERR : 0); node->pfd.events |= (io_write ? G_IO_OUT | G_IO_ERR : 0); } aio_epoll_update(ctx, node, is_new); aio_notify(ctx); if (deleted) { g_free(node); } } void aio_set_event_notifier(AioContext *ctx, EventNotifier *notifier, bool is_external, EventNotifierHandler *io_read) { aio_set_fd_handler(ctx, event_notifier_get_fd(notifier), is_external, (IOHandler *)io_read, NULL, notifier); } bool aio_prepare(AioContext *ctx) { return false; } bool aio_pending(AioContext *ctx) { AioHandler *node; QLIST_FOREACH(node, &ctx->aio_handlers, node) { int revents; revents = node->pfd.revents & node->pfd.events; if (revents & (G_IO_IN | G_IO_HUP | G_IO_ERR) && node->io_read && aio_node_check(ctx, node->is_external)) { return true; } if (revents & (G_IO_OUT | G_IO_ERR) && node->io_write && aio_node_check(ctx, node->is_external)) { return true; } } return false; } bool aio_dispatch(AioContext *ctx) { AioHandler *node; bool progress = false; /* * If there are callbacks left that have been queued, we need to call them. * Do not call select in this case, because it is possible that the caller * does not need a complete flush (as is the case for aio_poll loops). */ if (aio_bh_poll(ctx)) { progress = true; } /* * We have to walk very carefully in case aio_set_fd_handler is * called while we're walking. */ node = QLIST_FIRST(&ctx->aio_handlers); while (node) { AioHandler *tmp; int revents; ctx->walking_handlers++; revents = node->pfd.revents & node->pfd.events; node->pfd.revents = 0; if (!node->deleted && (revents & (G_IO_IN | G_IO_HUP | G_IO_ERR)) && aio_node_check(ctx, node->is_external) && node->io_read) { node->io_read(node->opaque); /* aio_notify() does not count as progress */ if (node->opaque != &ctx->notifier) { progress = true; } } if (!node->deleted && (revents & (G_IO_OUT | G_IO_ERR)) && aio_node_check(ctx, node->is_external) && node->io_write) { node->io_write(node->opaque); progress = true; } tmp = node; node = QLIST_NEXT(node, node); ctx->walking_handlers--; if (!ctx->walking_handlers && tmp->deleted) { QLIST_REMOVE(tmp, node); g_free(tmp); } } /* Run our timers */ progress |= timerlistgroup_run_timers(&ctx->tlg); return progress; } /* These thread-local variables are used only in a small part of aio_poll * around the call to the poll() system call. In particular they are not * used while aio_poll is performing callbacks, which makes it much easier * to think about reentrancy! * * Stack-allocated arrays would be perfect but they have size limitations; * heap allocation is expensive enough that we want to reuse arrays across * calls to aio_poll(). And because poll() has to be called without holding * any lock, the arrays cannot be stored in AioContext. Thread-local data * has none of the disadvantages of these three options. */ static __thread GPollFD *pollfds; static __thread AioHandler **nodes; static __thread unsigned npfd, nalloc; static __thread Notifier pollfds_cleanup_notifier; static void pollfds_cleanup(Notifier *n, void *unused) { g_assert(npfd == 0); g_free(pollfds); g_free(nodes); nalloc = 0; } static void add_pollfd(AioHandler *node) { if (npfd == nalloc) { if (nalloc == 0) { pollfds_cleanup_notifier.notify = pollfds_cleanup; qemu_thread_atexit_add(&pollfds_cleanup_notifier); nalloc = 8; } else { g_assert(nalloc <= INT_MAX); nalloc *= 2; } pollfds = g_renew(GPollFD, pollfds, nalloc); nodes = g_renew(AioHandler *, nodes, nalloc); } nodes[npfd] = node; pollfds[npfd] = (GPollFD) { .fd = node->pfd.fd, .events = node->pfd.events, }; npfd++; } bool aio_poll(AioContext *ctx, bool blocking) { AioHandler *node; int i, ret; bool progress; int64_t timeout; aio_context_acquire(ctx); progress = false; /* aio_notify can avoid the expensive event_notifier_set if * everything (file descriptors, bottom halves, timers) will * be re-evaluated before the next blocking poll(). This is * already true when aio_poll is called with blocking == false; * if blocking == true, it is only true after poll() returns, * so disable the optimization now. */ if (blocking) { atomic_add(&ctx->notify_me, 2); } ctx->walking_handlers++; assert(npfd == 0); /* fill pollfds */ if (!aio_epoll_enabled(ctx)) { QLIST_FOREACH(node, &ctx->aio_handlers, node) { if (!node->deleted && node->pfd.events && aio_node_check(ctx, node->is_external)) { add_pollfd(node); } } } timeout = blocking ? aio_compute_timeout(ctx) : 0; /* wait until next event */ if (timeout) { aio_context_release(ctx); } if (aio_epoll_check_poll(ctx, pollfds, npfd, timeout)) { AioHandler epoll_handler; epoll_handler.pfd.fd = ctx->epollfd; epoll_handler.pfd.events = G_IO_IN | G_IO_OUT | G_IO_HUP | G_IO_ERR; npfd = 0; add_pollfd(&epoll_handler); ret = aio_epoll(ctx, pollfds, npfd, timeout); } else { ret = qemu_poll_ns(pollfds, npfd, timeout); } if (blocking) { atomic_sub(&ctx->notify_me, 2); } if (timeout) { aio_context_acquire(ctx); } aio_notify_accept(ctx); /* if we have any readable fds, dispatch event */ if (ret > 0) { for (i = 0; i < npfd; i++) { nodes[i]->pfd.revents = pollfds[i].revents; } } npfd = 0; ctx->walking_handlers--; /* Run dispatch even if there were no readable fds to run timers */ if (aio_dispatch(ctx)) { progress = true; } aio_context_release(ctx); return progress; } void aio_context_setup(AioContext *ctx) { #ifdef CONFIG_EPOLL_CREATE1 assert(!ctx->epollfd); ctx->epollfd = epoll_create1(EPOLL_CLOEXEC); if (ctx->epollfd == -1) { fprintf(stderr, "Failed to create epoll instance: %s", strerror(errno)); ctx->epoll_available = false; } else { ctx->epoll_available = true; } #endif }