diff --git a/libknet/Makefile.am b/libknet/Makefile.am index c0bd4cfa..a0672528 100644 --- a/libknet/Makefile.am +++ b/libknet/Makefile.am @@ -1,130 +1,135 @@ # # Copyright (C) 2010-2017 Red Hat, Inc. All rights reserved. # # Authors: Fabio M. Di Nitto # Federico Simoncelli # # This software licensed under GPL-2.0+, LGPL-2.0+ # MAINTAINERCLEANFILES = Makefile.in include $(top_srcdir)/build-aux/check.mk SYMFILE = libknet_exported_syms EXTRA_DIST = $(SYMFILE) SUBDIRS = . tests man libversion = 1:0:0 # override global LIBS that pulls in lots of craft we don't need here LIBS = sources = \ common.c \ compat.c \ compress.c \ compress_zlib.c \ compress_lz4.c \ compress_lzo2.c \ compress_lzma.c \ compress_bzip2.c \ crypto.c \ crypto_nss.c \ crypto_openssl.c \ handle.c \ host.c \ links.c \ logging.c \ netutils.c \ threads_common.c \ threads_dsthandler.c \ threads_heartbeat.c \ threads_pmtud.c \ threads_rx.c \ threads_tx.c \ - transport_udp.c \ - transport_sctp.c \ + transports.c \ + transport_common.c \ transport_loopback.c \ - transport_common.c + transport_udp.c \ + transport_sctp.c include_HEADERS = libknet.h pkgconfigdir = $(libdir)/pkgconfig pkgconfig_DATA = libknet.pc noinst_HEADERS = \ common.h \ compat.h \ compress.h \ compress_bzip2.h \ compress_bzip2_remap.h \ compress_lz4.h \ compress_lz4_remap.h \ compress_lzma.h \ compress_lzma_remap.h \ compress_lzo2.h \ compress_lzo2_remap.h \ compress_zlib.h \ compress_zlib_remap.h \ crypto.h \ crypto_nss.h \ crypto_nss_remap.h \ crypto_openssl.h \ crypto_openssl_remap.h \ host.h \ internals.h \ links.h \ logging.h \ netutils.h \ onwire.h \ remap.h \ threads_common.h \ threads_dsthandler.h \ threads_heartbeat.h \ threads_pmtud.h \ threads_rx.h \ threads_tx.h \ - transports.h + transports.h \ + transport_common.h \ + transport_loopback.h \ + transport_udp.h \ + transport_sctp.h lib_LTLIBRARIES = libknet.la libknet_la_SOURCES = $(sources) libknet_la_CFLAGS = $(nss_CFLAGS) $(openssl_CFLAGS) \ $(zlib_CFLAGS) $(liblz4_CFLAGS) $(lzo2_CFLAGS) $(liblzma_CFLAGS) $(bzip2_CFLAGS) EXTRA_libknet_la_DEPENDENCIES = $(SYMFILE) libknet_la_LDFLAGS = -Wl,--version-script=$(srcdir)/$(SYMFILE) \ --export-dynamic \ -version-number $(libversion) libknet_la_LIBADD = $(dl_LIBS) $(pthread_LIBS) $(rt_LIBS) $(m_LIBS) noinst_PROGRAMS = crypto_canary compress_canary crypto_canary_SOURCES = crypto_canary.c crypto_canary_CFLAGS = $(nss_CFLAGS) $(openssl_CFLAGS) crypto_canary_LDADD = $(nss_LIBS) $(openssl_LIBS) compress_canary_SOURCES = compress_canary.c compress_canary_CFLAGS = $(zlib_CFLAGS) $(liblz4_CFLAGS) $(lzo2_CFLAGS) $(liblzma_CFLAGS) $(bzip2_CFLAGS) compress_canary_LDADD = $(zlib_LIBS) $(liblz4_LIBS) $(lzo2_LIBS) $(liblzma_LIBS) $(bzip2_LIBS) dist_man_MANS = man update-man-pages: doxyfile.stamp doxyfile.stamp: Doxyfile if MANPAGEUPDATES $(DOXYGEN) Doxyfile $(DOXY2MAN) -o $(abs_srcdir)/man -s 3 --short-pkg @PACKAGE_NAME@ --pkg "Kronosnet Programmer's Manual" $(builddir)/xml/libknet_8h.xml else @echo this system does not have doxy2man or doxygen installed. Unable to update man pages automatically. endif touch doxyfile.stamp clean-local: rm -rf doxyfile.stamp xml diff --git a/libknet/handle.c b/libknet/handle.c index 3ad8d627..d90fcfb3 100644 --- a/libknet/handle.c +++ b/libknet/handle.c @@ -1,1615 +1,1571 @@ /* * Copyright (C) 2010-2017 Red Hat, Inc. All rights reserved. * * Authors: Fabio M. Di Nitto * Federico Simoncelli * * This software licensed under GPL-2.0+, LGPL-2.0+ */ #include "config.h" #include #include #include #include #include #include #include #include #include #include "internals.h" #include "crypto.h" #include "links.h" #include "compress.h" #include "compat.h" #include "common.h" #include "threads_common.h" #include "threads_heartbeat.h" #include "threads_pmtud.h" #include "threads_dsthandler.h" #include "threads_rx.h" #include "threads_tx.h" #include "transports.h" +#include "transport_common.h" #include "logging.h" static pthread_mutex_t handle_config_mutex = PTHREAD_MUTEX_INITIALIZER; pthread_rwlock_t shlib_rwlock; static uint8_t shlib_wrlock_init = 0; static uint32_t knet_ref = 0; static int _init_shlib_tracker(knet_handle_t knet_h) { int savederrno = 0; if (!shlib_wrlock_init) { savederrno = pthread_rwlock_init(&shlib_rwlock, NULL); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to initialize shared lib rwlock: %s", strerror(savederrno)); errno = savederrno; return -1; } shlib_wrlock_init = 1; } return 0; } static void _fini_shlib_tracker(void) { if (knet_ref == 0) { pthread_rwlock_destroy(&shlib_rwlock); shlib_wrlock_init = 0; } return; } static int _init_locks(knet_handle_t knet_h) { int savederrno = 0; savederrno = pthread_rwlock_init(&knet_h->global_rwlock, NULL); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to initialize list rwlock: %s", strerror(savederrno)); goto exit_fail; } knet_h->lock_init_done = 1; savederrno = pthread_mutex_init(&knet_h->pmtud_mutex, NULL); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to initialize pmtud mutex: %s", strerror(savederrno)); goto exit_fail; } savederrno = pthread_cond_init(&knet_h->pmtud_cond, NULL); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to initialize pmtud conditional mutex: %s", strerror(savederrno)); goto exit_fail; } savederrno = pthread_mutex_init(&knet_h->hb_mutex, NULL); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to initialize hb_thread mutex: %s", strerror(savederrno)); goto exit_fail; } savederrno = pthread_mutex_init(&knet_h->tx_mutex, NULL); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to initialize tx_thread mutex: %s", strerror(savederrno)); goto exit_fail; } savederrno = pthread_mutex_init(&knet_h->tx_seq_num_mutex, NULL); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to initialize tx_seq_num_mutex mutex: %s", strerror(savederrno)); goto exit_fail; } return 0; exit_fail: errno = savederrno; return -1; } static void _destroy_locks(knet_handle_t knet_h) { knet_h->lock_init_done = 0; pthread_rwlock_destroy(&knet_h->global_rwlock); pthread_mutex_destroy(&knet_h->pmtud_mutex); pthread_cond_destroy(&knet_h->pmtud_cond); pthread_mutex_destroy(&knet_h->hb_mutex); pthread_mutex_destroy(&knet_h->tx_mutex); pthread_mutex_destroy(&knet_h->tx_seq_num_mutex); } static int _init_socks(knet_handle_t knet_h) { int savederrno = 0; if (_init_socketpair(knet_h, knet_h->hostsockfd)) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to initialize internal hostsockpair: %s", strerror(savederrno)); goto exit_fail; } if (_init_socketpair(knet_h, knet_h->dstsockfd)) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to initialize internal dstsockpair: %s", strerror(savederrno)); goto exit_fail; } return 0; exit_fail: errno = savederrno; return -1; } static void _close_socks(knet_handle_t knet_h) { _close_socketpair(knet_h, knet_h->dstsockfd); _close_socketpair(knet_h, knet_h->hostsockfd); } static int _init_buffers(knet_handle_t knet_h) { int savederrno = 0; int i; size_t bufsize; for (i = 0; i < PCKT_FRAG_MAX; i++) { bufsize = ceil((float)KNET_MAX_PACKET_SIZE / (i + 1)) + KNET_HEADER_ALL_SIZE; knet_h->send_to_links_buf[i] = malloc(bufsize); if (!knet_h->send_to_links_buf[i]) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to allocate memory datafd to link buffer: %s", strerror(savederrno)); goto exit_fail; } memset(knet_h->send_to_links_buf[i], 0, bufsize); } for (i = 0; i < PCKT_RX_BUFS; i++) { knet_h->recv_from_links_buf[i] = malloc(KNET_DATABUFSIZE); if (!knet_h->recv_from_links_buf[i]) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to allocate memory for link to datafd buffer: %s", strerror(savederrno)); goto exit_fail; } memset(knet_h->recv_from_links_buf[i], 0, KNET_DATABUFSIZE); } knet_h->recv_from_sock_buf = malloc(KNET_DATABUFSIZE); if (!knet_h->recv_from_sock_buf) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to allocate memory for app to datafd buffer: %s", strerror(savederrno)); goto exit_fail; } memset(knet_h->recv_from_sock_buf, 0, KNET_DATABUFSIZE); knet_h->pingbuf = malloc(KNET_HEADER_PING_SIZE); if (!knet_h->pingbuf) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to allocate memory for hearbeat buffer: %s", strerror(savederrno)); goto exit_fail; } memset(knet_h->pingbuf, 0, KNET_HEADER_PING_SIZE); knet_h->pmtudbuf = malloc(KNET_PMTUD_SIZE_V6); if (!knet_h->pmtudbuf) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to allocate memory for pmtud buffer: %s", strerror(savederrno)); goto exit_fail; } memset(knet_h->pmtudbuf, 0, KNET_PMTUD_SIZE_V6); for (i = 0; i < PCKT_FRAG_MAX; i++) { bufsize = ceil((float)KNET_MAX_PACKET_SIZE / (i + 1)) + KNET_HEADER_ALL_SIZE + KNET_DATABUFSIZE_CRYPT_PAD; knet_h->send_to_links_buf_crypt[i] = malloc(bufsize); if (!knet_h->send_to_links_buf_crypt[i]) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to allocate memory for crypto datafd to link buffer: %s", strerror(savederrno)); goto exit_fail; } memset(knet_h->send_to_links_buf_crypt[i], 0, bufsize); } knet_h->recv_from_links_buf_decrypt = malloc(KNET_DATABUFSIZE_CRYPT); if (!knet_h->recv_from_links_buf_decrypt) { savederrno = errno; log_err(knet_h, KNET_SUB_CRYPTO, "Unable to allocate memory for crypto link to datafd buffer: %s", strerror(savederrno)); goto exit_fail; } memset(knet_h->recv_from_links_buf_decrypt, 0, KNET_DATABUFSIZE_CRYPT); knet_h->recv_from_links_buf_crypt = malloc(KNET_DATABUFSIZE_CRYPT); if (!knet_h->recv_from_links_buf_crypt) { savederrno = errno; log_err(knet_h, KNET_SUB_CRYPTO, "Unable to allocate memory for crypto link to datafd buffer: %s", strerror(savederrno)); goto exit_fail; } memset(knet_h->recv_from_links_buf_crypt, 0, KNET_DATABUFSIZE_CRYPT); knet_h->pingbuf_crypt = malloc(KNET_DATABUFSIZE_CRYPT); if (!knet_h->pingbuf_crypt) { savederrno = errno; log_err(knet_h, KNET_SUB_CRYPTO, "Unable to allocate memory for crypto hearbeat buffer: %s", strerror(savederrno)); goto exit_fail; } memset(knet_h->pingbuf_crypt, 0, KNET_DATABUFSIZE_CRYPT); knet_h->pmtudbuf_crypt = malloc(KNET_DATABUFSIZE_CRYPT); if (!knet_h->pmtudbuf_crypt) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to allocate memory for crypto pmtud buffer: %s", strerror(savederrno)); goto exit_fail; } memset(knet_h->pmtudbuf_crypt, 0, KNET_DATABUFSIZE_CRYPT); knet_h->recv_from_links_buf_decompress = malloc(KNET_DATABUFSIZE_COMPRESS); if (!knet_h->recv_from_links_buf_decompress) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to allocate memory for decompress buffer: %s", strerror(savederrno)); goto exit_fail; } memset(knet_h->recv_from_links_buf_decompress, 0, KNET_DATABUFSIZE_COMPRESS); knet_h->send_to_links_buf_compress = malloc(KNET_DATABUFSIZE_COMPRESS); if (!knet_h->send_to_links_buf_compress) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to allocate memory for compress buffer: %s", strerror(savederrno)); goto exit_fail; } memset(knet_h->send_to_links_buf_compress, 0, KNET_DATABUFSIZE_COMPRESS); memset(knet_h->knet_transport_fd_tracker, KNET_MAX_TRANSPORTS, sizeof(knet_h->knet_transport_fd_tracker)); return 0; exit_fail: errno = savederrno; return -1; } static void _destroy_buffers(knet_handle_t knet_h) { int i; for (i = 0; i < PCKT_FRAG_MAX; i++) { free(knet_h->send_to_links_buf[i]); free(knet_h->send_to_links_buf_crypt[i]); } for (i = 0; i < PCKT_RX_BUFS; i++) { free(knet_h->recv_from_links_buf[i]); } free(knet_h->recv_from_links_buf_decompress); free(knet_h->send_to_links_buf_compress); free(knet_h->recv_from_sock_buf); free(knet_h->recv_from_links_buf_decrypt); free(knet_h->recv_from_links_buf_crypt); free(knet_h->pingbuf); free(knet_h->pingbuf_crypt); free(knet_h->pmtudbuf); free(knet_h->pmtudbuf_crypt); } static int _init_epolls(knet_handle_t knet_h) { struct epoll_event ev; int savederrno = 0; /* * even if the kernel does dynamic allocation with epoll_ctl * we need to reserve one extra for host to host communication */ knet_h->send_to_links_epollfd = epoll_create(KNET_EPOLL_MAX_EVENTS + 1); if (knet_h->send_to_links_epollfd < 0) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to create epoll datafd to link fd: %s", strerror(savederrno)); goto exit_fail; } knet_h->recv_from_links_epollfd = epoll_create(KNET_EPOLL_MAX_EVENTS); if (knet_h->recv_from_links_epollfd < 0) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to create epoll link to datafd fd: %s", strerror(savederrno)); goto exit_fail; } knet_h->dst_link_handler_epollfd = epoll_create(KNET_EPOLL_MAX_EVENTS); if (knet_h->dst_link_handler_epollfd < 0) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to create epoll dst cache fd: %s", strerror(savederrno)); goto exit_fail; } if (_fdset_cloexec(knet_h->send_to_links_epollfd)) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to set CLOEXEC on datafd to link epoll fd: %s", strerror(savederrno)); goto exit_fail; } if (_fdset_cloexec(knet_h->recv_from_links_epollfd)) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to set CLOEXEC on link to datafd epoll fd: %s", strerror(savederrno)); goto exit_fail; } if (_fdset_cloexec(knet_h->dst_link_handler_epollfd)) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to set CLOEXEC on dst cache epoll fd: %s", strerror(savederrno)); goto exit_fail; } memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLIN; ev.data.fd = knet_h->hostsockfd[0]; if (epoll_ctl(knet_h->send_to_links_epollfd, EPOLL_CTL_ADD, knet_h->hostsockfd[0], &ev)) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to add hostsockfd[0] to epoll pool: %s", strerror(savederrno)); goto exit_fail; } memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLIN; ev.data.fd = knet_h->dstsockfd[0]; if (epoll_ctl(knet_h->dst_link_handler_epollfd, EPOLL_CTL_ADD, knet_h->dstsockfd[0], &ev)) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to add dstsockfd[0] to epoll pool: %s", strerror(savederrno)); goto exit_fail; } return 0; exit_fail: errno = savederrno; return -1; } static void _close_epolls(knet_handle_t knet_h) { struct epoll_event ev; int i; memset(&ev, 0, sizeof(struct epoll_event)); for (i = 0; i < KNET_DATAFD_MAX; i++) { if (knet_h->sockfd[i].in_use) { epoll_ctl(knet_h->send_to_links_epollfd, EPOLL_CTL_DEL, knet_h->sockfd[i].sockfd[knet_h->sockfd[i].is_created], &ev); if (knet_h->sockfd[i].sockfd[knet_h->sockfd[i].is_created]) { _close_socketpair(knet_h, knet_h->sockfd[i].sockfd); } } } epoll_ctl(knet_h->send_to_links_epollfd, EPOLL_CTL_DEL, knet_h->hostsockfd[0], &ev); epoll_ctl(knet_h->dst_link_handler_epollfd, EPOLL_CTL_DEL, knet_h->dstsockfd[0], &ev); close(knet_h->send_to_links_epollfd); close(knet_h->recv_from_links_epollfd); close(knet_h->dst_link_handler_epollfd); } -static int _start_transports(knet_handle_t knet_h) -{ - int i, savederrno = 0, err = 0; - - for (i=0; itransport_ops[i] = get_udp_transport(); - break; - case KNET_TRANSPORT_SCTP: - knet_h->transport_ops[i] = get_sctp_transport(); - break; - case KNET_TRANSPORT_LOOPBACK: - knet_h->transport_ops[i] = get_loopback_transport(); - break; - } - - if (knet_h->transport_ops[i]) { - if (knet_h->transport_ops[i]->transport_init(knet_h) < 0) { - savederrno = errno; - log_err(knet_h, KNET_SUB_HANDLE, "Failed to allocate transport handle for %s: %s", - knet_h->transport_ops[i]->transport_name, - strerror(savederrno)); - err = -1; - goto out; - } - } - } - -out: - errno = savederrno; - return err; -} - -static void _stop_transports(knet_handle_t knet_h) -{ - int i; - - for (i=0; itransport_ops[i]) { - knet_h->transport_ops[i]->transport_free(knet_h); - } - } -} - static int _start_threads(knet_handle_t knet_h) { int savederrno = 0; savederrno = pthread_create(&knet_h->pmtud_link_handler_thread, 0, _handle_pmtud_link_thread, (void *) knet_h); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to start pmtud link thread: %s", strerror(savederrno)); goto exit_fail; } savederrno = pthread_create(&knet_h->dst_link_handler_thread, 0, _handle_dst_link_handler_thread, (void *) knet_h); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to start dst cache thread: %s", strerror(savederrno)); goto exit_fail; } savederrno = pthread_create(&knet_h->send_to_links_thread, 0, _handle_send_to_links_thread, (void *) knet_h); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to start datafd to link thread: %s", strerror(savederrno)); goto exit_fail; } savederrno = pthread_create(&knet_h->recv_from_links_thread, 0, _handle_recv_from_links_thread, (void *) knet_h); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to start link to datafd thread: %s", strerror(savederrno)); goto exit_fail; } savederrno = pthread_create(&knet_h->heartbt_thread, 0, _handle_heartbt_thread, (void *) knet_h); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to start heartbeat thread: %s", strerror(savederrno)); goto exit_fail; } return 0; exit_fail: errno = savederrno; return -1; } static void _stop_threads(knet_handle_t knet_h) { void *retval; /* * allow threads to catch on shutdown request * and release locks before we stop them. * this isn't the most efficent way to handle it * but it works good enough for now */ sleep(1); if (knet_h->heartbt_thread) { pthread_cancel(knet_h->heartbt_thread); pthread_join(knet_h->heartbt_thread, &retval); } if (knet_h->send_to_links_thread) { pthread_cancel(knet_h->send_to_links_thread); pthread_join(knet_h->send_to_links_thread, &retval); } if (knet_h->recv_from_links_thread) { pthread_cancel(knet_h->recv_from_links_thread); pthread_join(knet_h->recv_from_links_thread, &retval); } if (knet_h->dst_link_handler_thread) { pthread_cancel(knet_h->dst_link_handler_thread); pthread_join(knet_h->dst_link_handler_thread, &retval); } pthread_mutex_lock(&knet_h->pmtud_mutex); pthread_cond_signal(&knet_h->pmtud_cond); pthread_mutex_unlock(&knet_h->pmtud_mutex); sleep(1); if (knet_h->pmtud_link_handler_thread) { pthread_cancel(knet_h->pmtud_link_handler_thread); pthread_join(knet_h->pmtud_link_handler_thread, &retval); } } knet_handle_t knet_handle_new(knet_node_id_t host_id, int log_fd, uint8_t default_log_level) { knet_handle_t knet_h; int savederrno = 0; struct rlimit cur; if (getrlimit(RLIMIT_NOFILE, &cur) < 0) { return NULL; } if ((log_fd < 0) || ((unsigned int)log_fd >= cur.rlim_max)) { errno = EINVAL; return NULL; } /* * validate incoming request */ if ((log_fd) && (default_log_level > KNET_LOG_DEBUG)) { errno = EINVAL; return NULL; } /* * allocate handle */ knet_h = malloc(sizeof(struct knet_handle)); if (!knet_h) { errno = ENOMEM; return NULL; } memset(knet_h, 0, sizeof(struct knet_handle)); savederrno = pthread_mutex_lock(&handle_config_mutex); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get handle mutex lock: %s", strerror(savederrno)); errno = savederrno; goto exit_fail; } /* * copy config in place */ knet_h->host_id = host_id; knet_h->logfd = log_fd; if (knet_h->logfd > 0) { memset(&knet_h->log_levels, default_log_level, KNET_MAX_SUBSYSTEMS); } /* * set pmtud default timers */ knet_h->pmtud_interval = KNET_PMTUD_DEFAULT_INTERVAL; /* * set transports reconnect default timers */ knet_h->reconnect_int = KNET_TRANSPORT_DEFAULT_RECONNECT_INTERVAL; /* * Set 'min' stats to the maximum value so the * first value we get is always less */ knet_h->stats.tx_compress_time_min = UINT64_MAX; knet_h->stats.rx_compress_time_min = UINT64_MAX; knet_h->stats.tx_crypt_time_min = UINT64_MAX; knet_h->stats.rx_crypt_time_min = UINT64_MAX; /* * init global shlib tracker */ if (_init_shlib_tracker(knet_h) < 0) { savederrno = errno; log_err(knet_h, KNET_SUB_HANDLE, "Unable to init handles traceker: %s", strerror(savederrno)); errno = savederrno; goto exit_fail; } /* * init main locking structures */ if (_init_locks(knet_h)) { savederrno = errno; goto exit_fail; } /* * init sockets */ if (_init_socks(knet_h)) { savederrno = errno; goto exit_fail; } /* * allocate packet buffers */ if (_init_buffers(knet_h)) { savederrno = errno; goto exit_fail; } if (compress_init(knet_h)) { savederrno = errno; goto exit_fail; } /* * create epoll fds */ if (_init_epolls(knet_h)) { savederrno = errno; goto exit_fail; } /* * start transports */ - if (_start_transports(knet_h)) { + if (start_all_transports(knet_h)) { savederrno = errno; goto exit_fail; } /* * start internal threads */ if (_start_threads(knet_h)) { savederrno = errno; goto exit_fail; } knet_ref++; pthread_mutex_unlock(&handle_config_mutex); return knet_h; exit_fail: pthread_mutex_unlock(&handle_config_mutex); knet_handle_free(knet_h); errno = savederrno; return NULL; } int knet_handle_free(knet_handle_t knet_h) { int savederrno = 0; savederrno = pthread_mutex_lock(&handle_config_mutex); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get handle mutex lock: %s", strerror(savederrno)); errno = savederrno; return -1; } if (!knet_h) { pthread_mutex_unlock(&handle_config_mutex); errno = EINVAL; return -1; } if (!knet_h->lock_init_done) { goto exit_nolock; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get write lock: %s", strerror(savederrno)); pthread_mutex_unlock(&handle_config_mutex); errno = savederrno; return -1; } if (knet_h->host_head != NULL) { savederrno = EBUSY; log_err(knet_h, KNET_SUB_HANDLE, "Unable to free handle: host(s) or listener(s) are still active: %s", strerror(savederrno)); pthread_rwlock_unlock(&knet_h->global_rwlock); pthread_mutex_unlock(&handle_config_mutex); errno = savederrno; return -1; } knet_h->fini_in_progress = 1; pthread_rwlock_unlock(&knet_h->global_rwlock); _stop_threads(knet_h); - _stop_transports(knet_h); + stop_all_transports(knet_h); _close_epolls(knet_h); _destroy_buffers(knet_h); _close_socks(knet_h); crypto_fini(knet_h); compress_fini(knet_h, 1); _destroy_locks(knet_h); exit_nolock: free(knet_h); knet_h = NULL; knet_ref--; _fini_shlib_tracker(); pthread_mutex_unlock(&handle_config_mutex); return 0; } int knet_handle_enable_sock_notify(knet_handle_t knet_h, void *sock_notify_fn_private_data, void (*sock_notify_fn) ( void *private_data, int datafd, int8_t channel, uint8_t tx_rx, int error, int errorno)) { int savederrno = 0, err = 0; if (!knet_h) { errno = EINVAL; return -1; } if (!sock_notify_fn) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get write lock: %s", strerror(savederrno)); errno = savederrno; return -1; } knet_h->sock_notify_fn_private_data = sock_notify_fn_private_data; knet_h->sock_notify_fn = sock_notify_fn; log_debug(knet_h, KNET_SUB_HANDLE, "sock_notify_fn enabled"); pthread_rwlock_unlock(&knet_h->global_rwlock); return err; } int knet_handle_add_datafd(knet_handle_t knet_h, int *datafd, int8_t *channel) { int err = 0, savederrno = 0; int i; struct epoll_event ev; if (!knet_h) { errno = EINVAL; return -1; } if (datafd == NULL) { errno = EINVAL; return -1; } if (channel == NULL) { errno = EINVAL; return -1; } if (*channel >= KNET_DATAFD_MAX) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get write lock: %s", strerror(savederrno)); errno = savederrno; return -1; } if (!knet_h->sock_notify_fn) { log_err(knet_h, KNET_SUB_HANDLE, "Adding datafd requires sock notify callback enabled!"); savederrno = EINVAL; err = -1; goto out_unlock; } if (*datafd > 0) { for (i = 0; i < KNET_DATAFD_MAX; i++) { if ((knet_h->sockfd[i].in_use) && (knet_h->sockfd[i].sockfd[0] == *datafd)) { log_err(knet_h, KNET_SUB_HANDLE, "requested datafd: %d already exist in index: %d", *datafd, i); savederrno = EEXIST; err = -1; goto out_unlock; } } } /* * auto allocate a channel */ if (*channel < 0) { for (i = 0; i < KNET_DATAFD_MAX; i++) { if (!knet_h->sockfd[i].in_use) { *channel = i; break; } } if (*channel < 0) { savederrno = EBUSY; err = -1; goto out_unlock; } } else { if (knet_h->sockfd[*channel].in_use) { savederrno = EBUSY; err = -1; goto out_unlock; } } knet_h->sockfd[*channel].is_created = 0; knet_h->sockfd[*channel].is_socket = 0; knet_h->sockfd[*channel].has_error = 0; if (*datafd > 0) { int sockopt; socklen_t sockoptlen = sizeof(sockopt); if (_fdset_cloexec(*datafd)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_HANDLE, "Unable to set CLOEXEC on datafd: %s", strerror(savederrno)); goto out_unlock; } if (_fdset_nonblock(*datafd)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_HANDLE, "Unable to set NONBLOCK on datafd: %s", strerror(savederrno)); goto out_unlock; } knet_h->sockfd[*channel].sockfd[0] = *datafd; knet_h->sockfd[*channel].sockfd[1] = 0; if (!getsockopt(knet_h->sockfd[*channel].sockfd[0], SOL_SOCKET, SO_TYPE, &sockopt, &sockoptlen)) { knet_h->sockfd[*channel].is_socket = 1; } } else { if (_init_socketpair(knet_h, knet_h->sockfd[*channel].sockfd)) { savederrno = errno; err = -1; goto out_unlock; } knet_h->sockfd[*channel].is_created = 1; knet_h->sockfd[*channel].is_socket = 1; *datafd = knet_h->sockfd[*channel].sockfd[0]; } memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLIN; ev.data.fd = knet_h->sockfd[*channel].sockfd[knet_h->sockfd[*channel].is_created]; if (epoll_ctl(knet_h->send_to_links_epollfd, EPOLL_CTL_ADD, knet_h->sockfd[*channel].sockfd[knet_h->sockfd[*channel].is_created], &ev)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_HANDLE, "Unable to add datafd %d to linkfd epoll pool: %s", knet_h->sockfd[*channel].sockfd[knet_h->sockfd[*channel].is_created], strerror(savederrno)); if (knet_h->sockfd[*channel].is_created) { _close_socketpair(knet_h, knet_h->sockfd[*channel].sockfd); } goto out_unlock; } knet_h->sockfd[*channel].in_use = 1; out_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_handle_remove_datafd(knet_handle_t knet_h, int datafd) { int err = 0, savederrno = 0; int8_t channel = -1; int i; struct epoll_event ev; if (!knet_h) { errno = EINVAL; return -1; } if (datafd <= 0) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get write lock: %s", strerror(savederrno)); errno = savederrno; return -1; } for (i = 0; i < KNET_DATAFD_MAX; i++) { if ((knet_h->sockfd[i].in_use) && (knet_h->sockfd[i].sockfd[0] == datafd)) { channel = i; break; } } if (channel < 0) { savederrno = EINVAL; err = -1; goto out_unlock; } if (!knet_h->sockfd[channel].has_error) { memset(&ev, 0, sizeof(struct epoll_event)); if (epoll_ctl(knet_h->send_to_links_epollfd, EPOLL_CTL_DEL, knet_h->sockfd[channel].sockfd[knet_h->sockfd[channel].is_created], &ev)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_HANDLE, "Unable to del datafd %d from linkfd epoll pool: %s", knet_h->sockfd[channel].sockfd[0], strerror(savederrno)); goto out_unlock; } } if (knet_h->sockfd[channel].is_created) { _close_socketpair(knet_h, knet_h->sockfd[channel].sockfd); } memset(&knet_h->sockfd[channel], 0, sizeof(struct knet_sock)); out_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_handle_get_datafd(knet_handle_t knet_h, const int8_t channel, int *datafd) { int err = 0, savederrno = 0; if (!knet_h) { errno = EINVAL; return -1; } if ((channel < 0) || (channel >= KNET_DATAFD_MAX)) { errno = EINVAL; return -1; } if (datafd == NULL) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get read lock: %s", strerror(savederrno)); errno = savederrno; return -1; } if (!knet_h->sockfd[channel].in_use) { savederrno = EINVAL; err = -1; goto out_unlock; } *datafd = knet_h->sockfd[channel].sockfd[0]; out_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_handle_get_channel(knet_handle_t knet_h, const int datafd, int8_t *channel) { int err = 0, savederrno = 0; int i; if (!knet_h) { errno = EINVAL; return -1; } if (datafd <= 0) { errno = EINVAL; return -1; } if (channel == NULL) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get read lock: %s", strerror(savederrno)); errno = savederrno; return -1; } *channel = -1; for (i = 0; i < KNET_DATAFD_MAX; i++) { if ((knet_h->sockfd[i].in_use) && (knet_h->sockfd[i].sockfd[0] == datafd)) { *channel = i; break; } } if (*channel < 0) { savederrno = EINVAL; err = -1; goto out_unlock; } out_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_handle_enable_filter(knet_handle_t knet_h, void *dst_host_filter_fn_private_data, int (*dst_host_filter_fn) ( void *private_data, const unsigned char *outdata, ssize_t outdata_len, uint8_t tx_rx, knet_node_id_t this_host_id, knet_node_id_t src_node_id, int8_t *channel, knet_node_id_t *dst_host_ids, size_t *dst_host_ids_entries)) { int savederrno = 0; if (!knet_h) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get write lock: %s", strerror(savederrno)); errno = savederrno; return -1; } knet_h->dst_host_filter_fn_private_data = dst_host_filter_fn_private_data; knet_h->dst_host_filter_fn = dst_host_filter_fn; if (knet_h->dst_host_filter_fn) { log_debug(knet_h, KNET_SUB_HANDLE, "dst_host_filter_fn enabled"); } else { log_debug(knet_h, KNET_SUB_HANDLE, "dst_host_filter_fn disabled"); } pthread_rwlock_unlock(&knet_h->global_rwlock); return 0; } int knet_handle_setfwd(knet_handle_t knet_h, unsigned int enabled) { int savederrno = 0; if (!knet_h) { errno = EINVAL; return -1; } if (enabled > 1) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get write lock: %s", strerror(savederrno)); errno = savederrno; return -1; } knet_h->enabled = enabled; if (enabled) { log_debug(knet_h, KNET_SUB_HANDLE, "Data forwarding is enabled"); } else { log_debug(knet_h, KNET_SUB_HANDLE, "Data forwarding is disabled"); } pthread_rwlock_unlock(&knet_h->global_rwlock); return 0; } int knet_handle_pmtud_getfreq(knet_handle_t knet_h, unsigned int *interval) { int savederrno = 0; if (!knet_h) { errno = EINVAL; return -1; } if (!interval) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get read lock: %s", strerror(savederrno)); errno = savederrno; return -1; } *interval = knet_h->pmtud_interval; pthread_rwlock_unlock(&knet_h->global_rwlock); return 0; } int knet_handle_pmtud_setfreq(knet_handle_t knet_h, unsigned int interval) { int savederrno = 0; if (!knet_h) { errno = EINVAL; return -1; } if ((!interval) || (interval > 86400)) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get write lock: %s", strerror(savederrno)); errno = savederrno; return -1; } knet_h->pmtud_interval = interval; log_debug(knet_h, KNET_SUB_HANDLE, "PMTUd interval set to: %u seconds", interval); pthread_rwlock_unlock(&knet_h->global_rwlock); return 0; } int knet_handle_enable_pmtud_notify(knet_handle_t knet_h, void *pmtud_notify_fn_private_data, void (*pmtud_notify_fn) ( void *private_data, unsigned int data_mtu)) { int savederrno = 0; if (!knet_h) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get write lock: %s", strerror(savederrno)); errno = savederrno; return -1; } knet_h->pmtud_notify_fn_private_data = pmtud_notify_fn_private_data; knet_h->pmtud_notify_fn = pmtud_notify_fn; if (knet_h->pmtud_notify_fn) { log_debug(knet_h, KNET_SUB_HANDLE, "pmtud_notify_fn enabled"); } else { log_debug(knet_h, KNET_SUB_HANDLE, "pmtud_notify_fn disabled"); } pthread_rwlock_unlock(&knet_h->global_rwlock); return 0; } int knet_handle_pmtud_get(knet_handle_t knet_h, unsigned int *data_mtu) { int savederrno = 0; if (!knet_h) { errno = EINVAL; return -1; } if (!data_mtu) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get read lock: %s", strerror(savederrno)); errno = savederrno; return -1; } *data_mtu = knet_h->data_mtu; pthread_rwlock_unlock(&knet_h->global_rwlock); return 0; } int knet_handle_crypto(knet_handle_t knet_h, struct knet_handle_crypto_cfg *knet_handle_crypto_cfg) { int savederrno = 0; int err = 0; if (!knet_h) { errno = EINVAL; return -1; } if (!knet_handle_crypto_cfg) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get write lock: %s", strerror(savederrno)); errno = savederrno; return -1; } crypto_fini(knet_h); if ((!strncmp("none", knet_handle_crypto_cfg->crypto_model, 4)) || ((!strncmp("none", knet_handle_crypto_cfg->crypto_cipher_type, 4)) && (!strncmp("none", knet_handle_crypto_cfg->crypto_hash_type, 4)))) { log_debug(knet_h, KNET_SUB_CRYPTO, "crypto is not enabled"); err = 0; goto exit_unlock; } if (knet_handle_crypto_cfg->private_key_len < KNET_MIN_KEY_LEN) { log_debug(knet_h, KNET_SUB_CRYPTO, "private key len too short (min %d): %u", KNET_MIN_KEY_LEN, knet_handle_crypto_cfg->private_key_len); savederrno = EINVAL; err = -1; goto exit_unlock; } if (knet_handle_crypto_cfg->private_key_len > KNET_MAX_KEY_LEN) { log_debug(knet_h, KNET_SUB_CRYPTO, "private key len too long (max %d): %u", KNET_MAX_KEY_LEN, knet_handle_crypto_cfg->private_key_len); savederrno = EINVAL; err = -1; goto exit_unlock; } err = crypto_init(knet_h, knet_handle_crypto_cfg); if (err) { err = -2; } exit_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_handle_compress(knet_handle_t knet_h, struct knet_handle_compress_cfg *knet_handle_compress_cfg) { int savederrno = 0; int err = 0; if (!knet_h) { errno = EINVAL; return -1; } if (!knet_handle_compress_cfg) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get write lock: %s", strerror(savederrno)); errno = savederrno; return -1; } compress_fini(knet_h, 0); err = compress_cfg(knet_h, knet_handle_compress_cfg); savederrno = errno; pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } ssize_t knet_recv(knet_handle_t knet_h, char *buff, const size_t buff_len, const int8_t channel) { int savederrno = 0; ssize_t err = 0; struct iovec iov_in; if (!knet_h) { errno = EINVAL; return -1; } if (buff == NULL) { errno = EINVAL; return -1; } if (buff_len <= 0) { errno = EINVAL; return -1; } if (buff_len > KNET_MAX_PACKET_SIZE) { errno = EINVAL; return -1; } if (channel < 0) { errno = EINVAL; return -1; } if (channel >= KNET_DATAFD_MAX) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get read lock: %s", strerror(savederrno)); errno = savederrno; return -1; } if (!knet_h->sockfd[channel].in_use) { savederrno = EINVAL; err = -1; goto out_unlock; } memset(&iov_in, 0, sizeof(iov_in)); iov_in.iov_base = (void *)buff; iov_in.iov_len = buff_len; err = readv(knet_h->sockfd[channel].sockfd[0], &iov_in, 1); savederrno = errno; out_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } ssize_t knet_send(knet_handle_t knet_h, const char *buff, const size_t buff_len, const int8_t channel) { int savederrno = 0; ssize_t err = 0; struct iovec iov_out[1]; if (!knet_h) { errno = EINVAL; return -1; } if (buff == NULL) { errno = EINVAL; return -1; } if (buff_len <= 0) { errno = EINVAL; return -1; } if (buff_len > KNET_MAX_PACKET_SIZE) { errno = EINVAL; return -1; } if (channel < 0) { errno = EINVAL; return -1; } if (channel >= KNET_DATAFD_MAX) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get read lock: %s", strerror(savederrno)); errno = savederrno; return -1; } if (!knet_h->sockfd[channel].in_use) { savederrno = EINVAL; err = -1; goto out_unlock; } memset(iov_out, 0, sizeof(iov_out)); iov_out[0].iov_base = (void *)buff; iov_out[0].iov_len = buff_len; err = writev(knet_h->sockfd[channel].sockfd[0], iov_out, 1); savederrno = errno; out_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_handle_get_stats(knet_handle_t knet_h, struct knet_handle_stats *stats, size_t struct_size) { int savederrno = 0; int err = 0; if (!knet_h) { errno = EINVAL; return -1; } if (!stats) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get write lock: %s", strerror(savederrno)); errno = savederrno; return -1; } if (struct_size > sizeof(struct knet_handle_stats)) { struct_size = sizeof(struct knet_handle_stats); } memmove(stats, &knet_h->stats, struct_size); /* Tell the caller our full size in case they have an old version */ stats->size = sizeof(struct knet_handle_stats); pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_handle_clear_stats(knet_handle_t knet_h, int clear_option) { int savederrno = 0; int err = 0; if (!knet_h) { errno = EINVAL; return -1; } if (clear_option != KNET_CLEARSTATS_HANDLE_ONLY && clear_option != KNET_CLEARSTATS_HANDLE_AND_LINK) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_HANDLE, "Unable to get write lock: %s", strerror(savederrno)); errno = savederrno; return -1; } memset(&knet_h->stats, 0, sizeof(struct knet_handle_stats)); if (clear_option == KNET_CLEARSTATS_HANDLE_AND_LINK) { _link_clear_stats(knet_h); } pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } diff --git a/libknet/internals.h b/libknet/internals.h index 048590aa..762c0d48 100644 --- a/libknet/internals.h +++ b/libknet/internals.h @@ -1,488 +1,489 @@ /* * Copyright (C) 2010-2017 Red Hat, Inc. All rights reserved. * * Authors: Fabio M. Di Nitto * Federico Simoncelli * * This software licensed under GPL-2.0+, LGPL-2.0+ */ #ifndef __KNET_INTERNALS_H__ #define __KNET_INTERNALS_H__ /* * NOTE: you shouldn't need to include this header normally */ #include #include "libknet.h" #include "onwire.h" #include "compat.h" #define KNET_DATABUFSIZE KNET_MAX_PACKET_SIZE + KNET_HEADER_ALL_SIZE #define KNET_DATABUFSIZE_CRYPT_PAD 1024 #define KNET_DATABUFSIZE_CRYPT KNET_DATABUFSIZE + KNET_DATABUFSIZE_CRYPT_PAD #define KNET_DATABUFSIZE_COMPRESS_PAD 1024 #define KNET_DATABUFSIZE_COMPRESS KNET_DATABUFSIZE + KNET_DATABUFSIZE_COMPRESS_PAD #define KNET_RING_RCVBUFF 8388608 #define PCKT_FRAG_MAX UINT8_MAX #define PCKT_RX_BUFS 512 #define KNET_EPOLL_MAX_EVENTS KNET_DATAFD_MAX typedef void *knet_transport_link_t; /* per link transport handle */ typedef void *knet_transport_t; /* per knet_h transport handle */ struct knet_transport_ops; /* Forward because of circular dependancy */ struct knet_mmsghdr { struct msghdr msg_hdr; /* Message header */ unsigned int msg_len; /* Number of bytes transmitted */ }; struct knet_link { /* required */ struct sockaddr_storage src_addr; struct sockaddr_storage dst_addr; /* configurable */ unsigned int dynamic; /* see KNET_LINK_DYN_ define above */ uint8_t priority; /* higher priority == preferred for A/P */ unsigned long long ping_interval; /* interval */ unsigned long long pong_timeout; /* timeout */ unsigned int latency_fix; /* precision */ uint8_t pong_count; /* how many ping/pong to send/receive before link is up */ uint64_t flags; /* status */ struct knet_link_status status; /* internals */ uint8_t link_id; uint8_t transport_type; /* #defined constant from API */ knet_transport_link_t transport_link; /* link_info_t from transport */ int outsock; unsigned int configured:1; /* set to 1 if src/dst have been configured transport initialized on this link*/ unsigned int transport_connected:1; /* set to 1 if lower level transport is connected */ unsigned int latency_exp; uint8_t received_pong; struct timespec ping_last; /* used by PMTUD thread as temp per-link variables and should always contain the onwire_len value! */ uint32_t proto_overhead; struct timespec pmtud_last; uint32_t last_ping_size; uint32_t last_good_mtu; uint32_t last_bad_mtu; uint32_t last_sent_mtu; uint32_t last_recv_mtu; uint8_t has_valid_mtu; }; #define KNET_CBUFFER_SIZE 4096 struct knet_host_defrag_buf { char buf[KNET_DATABUFSIZE]; uint8_t in_use; /* 0 buffer is free, 1 is in use */ seq_num_t pckt_seq; /* identify the pckt we are receiving */ uint8_t frag_recv; /* how many frags did we receive */ uint8_t frag_map[PCKT_FRAG_MAX];/* bitmap of what we received? */ uint8_t last_first; /* special case if we receive the last fragment first */ uint16_t frag_size; /* normal frag size (not the last one) */ uint16_t last_frag_size; /* the last fragment might not be aligned with MTU size */ struct timespec last_update; /* keep time of the last pckt */ }; struct knet_host { /* required */ knet_node_id_t host_id; /* configurable */ uint8_t link_handler_policy; char name[KNET_MAX_HOST_LEN]; /* status */ struct knet_host_status status; /* internals */ char circular_buffer[KNET_CBUFFER_SIZE]; seq_num_t rx_seq_num; seq_num_t untimed_rx_seq_num; seq_num_t timed_rx_seq_num; uint8_t got_data; /* defrag/reassembly buffers */ struct knet_host_defrag_buf defrag_buf[KNET_MAX_LINK]; char circular_buffer_defrag[KNET_CBUFFER_SIZE]; /* link stuff */ struct knet_link link[KNET_MAX_LINK]; uint8_t active_link_entries; uint8_t active_links[KNET_MAX_LINK]; struct knet_host *next; }; struct knet_sock { int sockfd[2]; /* sockfd[0] will always be application facing * and sockfd[1] internal if sockpair has been created by knet */ int is_socket; /* check if it's a socket for recvmmsg usage */ int is_created; /* knet created this socket and has to clean up on exit/del */ int in_use; /* set to 1 if it's use, 0 if free */ int has_error; /* set to 1 if there were errors reading from the sock * and socket has been removed from epoll */ }; struct knet_fd_trackers { uint8_t transport; /* transport type (UDP/SCTP...) */ uint8_t data_type; /* internal use for transport to define what data are associated * to this fd */ void *data; /* pointer to the data */ }; #define KNET_MAX_FDS KNET_MAX_HOST * KNET_MAX_LINK * 4 #define KNET_MAX_COMPRESS_METHODS UINT8_MAX struct knet_handle { knet_node_id_t host_id; unsigned int enabled:1; struct knet_sock sockfd[KNET_DATAFD_MAX]; int logfd; uint8_t log_levels[KNET_MAX_SUBSYSTEMS]; int hostsockfd[2]; int dstsockfd[2]; int send_to_links_epollfd; int recv_from_links_epollfd; int dst_link_handler_epollfd; unsigned int pmtud_interval; unsigned int data_mtu; /* contains the max data size that we can send onwire * without frags */ struct knet_host *host_head; struct knet_host *host_index[KNET_MAX_HOST]; knet_transport_t transports[KNET_MAX_TRANSPORTS+1]; - struct knet_transport_ops *transport_ops[KNET_MAX_TRANSPORTS+1]; struct knet_fd_trackers knet_transport_fd_tracker[KNET_MAX_FDS]; /* track status for each fd handled by transports */ struct knet_handle_stats stats; uint32_t reconnect_int; knet_node_id_t host_ids[KNET_MAX_HOST]; size_t host_ids_entries; struct knet_header *recv_from_sock_buf; struct knet_header *send_to_links_buf[PCKT_FRAG_MAX]; struct knet_header *recv_from_links_buf[PCKT_RX_BUFS]; struct knet_header *pingbuf; struct knet_header *pmtudbuf; pthread_t send_to_links_thread; pthread_t recv_from_links_thread; pthread_t heartbt_thread; pthread_t dst_link_handler_thread; pthread_t pmtud_link_handler_thread; int lock_init_done; pthread_rwlock_t global_rwlock; /* global config lock */ pthread_mutex_t pmtud_mutex; /* pmtud mutex to handle conditional send/recv + timeout */ pthread_cond_t pmtud_cond; /* conditional for above */ pthread_mutex_t tx_mutex; /* used to protect knet_send_sync and TX thread */ pthread_mutex_t hb_mutex; /* used to protect heartbeat thread and seq_num broadcasting */ struct crypto_instance *crypto_instance; size_t sec_header_size; size_t sec_block_size; size_t sec_hash_size; size_t sec_salt_size; unsigned char *send_to_links_buf_crypt[PCKT_FRAG_MAX]; unsigned char *recv_from_links_buf_crypt; unsigned char *recv_from_links_buf_decrypt; unsigned char *pingbuf_crypt; unsigned char *pmtudbuf_crypt; int compress_model; int compress_level; size_t compress_threshold; void *compress_int_data[KNET_MAX_COMPRESS_METHODS]; /* for compress method private data */ unsigned char *recv_from_links_buf_decompress; unsigned char *send_to_links_buf_compress; seq_num_t tx_seq_num; pthread_mutex_t tx_seq_num_mutex; uint8_t has_loop_link; uint8_t loop_link; void *dst_host_filter_fn_private_data; int (*dst_host_filter_fn) ( void *private_data, const unsigned char *outdata, ssize_t outdata_len, uint8_t tx_rx, knet_node_id_t this_host_id, knet_node_id_t src_node_id, int8_t *channel, knet_node_id_t *dst_host_ids, size_t *dst_host_ids_entries); void *pmtud_notify_fn_private_data; void (*pmtud_notify_fn) ( void *private_data, unsigned int data_mtu); void *host_status_change_notify_fn_private_data; void (*host_status_change_notify_fn) ( void *private_data, knet_node_id_t host_id, uint8_t reachable, uint8_t remote, uint8_t external); void *sock_notify_fn_private_data; void (*sock_notify_fn) ( void *private_data, int datafd, int8_t channel, uint8_t tx_rx, int error, int errorno); int fini_in_progress; }; extern pthread_rwlock_t shlib_rwlock; /* global shared lib load lock */ /* * NOTE: every single operation must be implementend * for every protocol. */ typedef struct knet_transport_ops { /* * transport generic information */ const char *transport_name; const uint8_t transport_id; + const uint8_t built_in; + uint32_t transport_mtu_overhead; /* * transport init must allocate the new transport * and perform all internal initializations * (threads, lists, etc). */ int (*transport_init)(knet_handle_t knet_h); /* * transport free must releases _all_ resources * allocated by tranport_init */ int (*transport_free)(knet_handle_t knet_h); /* * link operations should take care of all the * sockets and epoll management for a given link/transport set * transport_link_disable should return err = -1 and errno = EBUSY * if listener is still in use, and any other errno in case * the link cannot be disabled. * * set_config/clear_config are invoked in global write lock context */ int (*transport_link_set_config)(knet_handle_t knet_h, struct knet_link *link); int (*transport_link_clear_config)(knet_handle_t knet_h, struct knet_link *link); /* * transport callback for incoming dynamic connections * this is called in global read lock context */ int (*transport_link_dyn_connect)(knet_handle_t knet_h, int sockfd, struct knet_link *link); /* * per transport error handling of recvmmsg * (see _handle_recv_from_links comments for details) */ /* * transport_rx_sock_error is invoked when recvmmsg returns <= 0 * * transport_rx_sock_error is invoked with both global_rdlock */ int (*transport_rx_sock_error)(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno); /* * transport_tx_sock_error is invoked with global_rwlock and * it's invoked when sendto or sendmmsg returns =< 0 * * it should return: * -1 on internal error * 0 ignore error and continue * 1 retry * any sleep or wait action should happen inside the transport code */ int (*transport_tx_sock_error)(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno); /* * this function is called on _every_ received packet * to verify if the packet is data or internal protocol error handling * * it should return: * -1 on error * 0 packet is not data and we should continue the packet process loop * 1 packet is not data and we should STOP the packet process loop * 2 packet is data and should be parsed as such * * transport_rx_is_data is invoked with both global_rwlock * and fd_tracker read lock (from RX thread) */ int (*transport_rx_is_data)(knet_handle_t knet_h, int sockfd, struct knet_mmsghdr *msg); } knet_transport_ops_t; socklen_t sockaddr_len(const struct sockaddr_storage *ss); /** * This is a kernel style list implementation. * * @author Steven Dake */ struct knet_list_head { struct knet_list_head *next; struct knet_list_head *prev; }; /** * @def KNET_LIST_DECLARE() * Declare and initialize a list head. */ #define KNET_LIST_DECLARE(name) \ struct knet_list_head name = { &(name), &(name) } #define KNET_INIT_LIST_HEAD(ptr) do { \ (ptr)->next = (ptr); (ptr)->prev = (ptr); \ } while (0) /** * Initialize the list entry. * * Points next and prev pointers to head. * @param head pointer to the list head */ static inline void knet_list_init(struct knet_list_head *head) { head->next = head; head->prev = head; } /** * Add this element to the list. * * @param element the new element to insert. * @param head pointer to the list head */ static inline void knet_list_add(struct knet_list_head *element, struct knet_list_head *head) { head->next->prev = element; element->next = head->next; element->prev = head; head->next = element; } /** * Add to the list (but at the end of the list). * * @param element pointer to the element to add * @param head pointer to the list head * @see knet_list_add() */ static inline void knet_list_add_tail(struct knet_list_head *element, struct knet_list_head *head) { head->prev->next = element; element->next = head; element->prev = head->prev; head->prev = element; } /** * Delete an entry from the list. * * @param _remove the list item to remove */ static inline void knet_list_del(struct knet_list_head *_remove) { _remove->next->prev = _remove->prev; _remove->prev->next = _remove->next; } /** * Replace old entry by new one * @param old: the element to be replaced * @param new: the new element to insert */ static inline void knet_list_replace(struct knet_list_head *old, struct knet_list_head *new) { new->next = old->next; new->next->prev = new; new->prev = old->prev; new->prev->next = new; } /** * Tests whether list is the last entry in list head * @param list: the entry to test * @param head: the head of the list * @return boolean true/false */ static inline int knet_list_is_last(const struct knet_list_head *list, const struct knet_list_head *head) { return list->next == head; } /** * A quick test to see if the list is empty (pointing to it's self). * @param head pointer to the list head * @return boolean true/false */ static inline int32_t knet_list_empty(const struct knet_list_head *head) { return head->next == head; } /** * Get the struct for this entry * @param ptr: the &struct list_head pointer. * @param type: the type of the struct this is embedded in. * @param member: the name of the list_struct within the struct. */ #define knet_list_entry(ptr,type,member)\ ((type *)((char *)(ptr)-(char*)(&((type *)0)->member))) /** * Get the first element from a list * @param ptr: the &struct list_head pointer. * @param type: the type of the struct this is embedded in. * @param member: the name of the list_struct within the struct. */ #define knet_list_first_entry(ptr, type, member) \ knet_list_entry((ptr)->next, type, member) /** * Iterate over a list * @param pos: the &struct list_head to use as a loop counter. * @param head: the head for your list. */ #define knet_list_for_each(pos, head) \ for (pos = (head)->next; pos != (head); pos = pos->next) /** * Iterate over a list backwards * @param pos: the &struct list_head to use as a loop counter. * @param head: the head for your list. */ #define knet_list_for_each_reverse(pos, head) \ for (pos = (head)->prev; pos != (head); pos = pos->prev) /** * Iterate over a list safe against removal of list entry * @param pos: the &struct list_head to use as a loop counter. * @param n: another &struct list_head to use as temporary storage * @param head: the head for your list. */ #define knet_list_for_each_safe(pos, n, head) \ for (pos = (head)->next, n = pos->next; pos != (head); \ pos = n, n = pos->next) /** * Iterate over list of given type * @param pos: the type * to use as a loop counter. * @param head: the head for your list. * @param member: the name of the list_struct within the struct. */ #define knet_list_for_each_entry(pos, head, member) \ for (pos = knet_list_entry((head)->next, typeof(*pos), member); \ &pos->member != (head); \ pos = knet_list_entry(pos->member.next, typeof(*pos), member)) #endif diff --git a/libknet/links.c b/libknet/links.c index 8d7bfe77..88bbfc84 100644 --- a/libknet/links.c +++ b/libknet/links.c @@ -1,1087 +1,1079 @@ /* * Copyright (C) 2012-2017 Red Hat, Inc. All rights reserved. * * Authors: Fabio M. Di Nitto * Federico Simoncelli * * This software licensed under GPL-2.0+, LGPL-2.0+ */ #include "config.h" #include #include #include #include #include "internals.h" #include "logging.h" #include "links.h" #include "transports.h" #include "host.h" int _link_updown(knet_handle_t knet_h, knet_node_id_t host_id, uint8_t link_id, unsigned int enabled, unsigned int connected) { struct knet_link *link = &knet_h->host_index[host_id]->link[link_id]; if ((link->status.enabled == enabled) && (link->status.connected == connected)) return 0; link->status.enabled = enabled; link->status.connected = connected; _host_dstcache_update_async(knet_h, knet_h->host_index[host_id]); if ((link->status.dynconnected) && (!link->status.connected)) link->status.dynconnected = 0; if (connected) { time(&link->status.stats.last_up_times[link->status.stats.last_up_time_index]); link->status.stats.up_count++; if (++link->status.stats.last_up_time_index > MAX_LINK_EVENTS) { link->status.stats.last_up_time_index = 0; } } else { time(&link->status.stats.last_down_times[link->status.stats.last_down_time_index]); link->status.stats.down_count++; if (++link->status.stats.last_down_time_index > MAX_LINK_EVENTS) { link->status.stats.last_down_time_index = 0; } } return 0; } void _link_clear_stats(knet_handle_t knet_h) { struct knet_host *host; struct knet_link *link; uint32_t host_id; uint8_t link_id; for (host_id = 0; host_id < KNET_MAX_HOST; host_id++) { host = knet_h->host_index[host_id]; if (!host) { continue; } for (link_id = 0; link_id < KNET_MAX_LINK; link_id++) { link = &host->link[link_id]; memset(&link->status.stats, 0, sizeof(struct knet_link_stats)); } } } int knet_link_set_config(knet_handle_t knet_h, knet_node_id_t host_id, uint8_t link_id, uint8_t transport, struct sockaddr_storage *src_addr, struct sockaddr_storage *dst_addr, uint64_t flags) { int savederrno = 0, err = 0, i; struct knet_host *host; struct knet_link *link; if (!knet_h) { errno = EINVAL; return -1; } if (link_id >= KNET_MAX_LINK) { errno = EINVAL; return -1; } if (!src_addr) { errno = EINVAL; return -1; } if (transport >= KNET_MAX_TRANSPORTS) { errno = EINVAL; return -1; } - if (!knet_h->transport_ops[transport]) { - errno = EINVAL; - return -1; - } - savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_LINK, "Unable to get write lock: %s", strerror(savederrno)); errno = savederrno; return -1; } if (transport == KNET_TRANSPORT_LOOPBACK && knet_h->host_id != host_id) { log_err(knet_h, KNET_SUB_LINK, "Cannot create loopback link to remote node"); err = -1; savederrno = EINVAL; goto exit_unlock; } if (knet_h->host_id == host_id && knet_h->has_loop_link) { log_err(knet_h, KNET_SUB_LINK, "Cannot create more than 1 link when loopback is active"); err = -1; savederrno = EINVAL; goto exit_unlock; } host = knet_h->host_index[host_id]; if (!host) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "Unable to find host %u: %s", host_id, strerror(savederrno)); goto exit_unlock; } if (transport == KNET_TRANSPORT_LOOPBACK && knet_h->host_id == host_id) { for (i=0; ilink[i].configured) { log_err(knet_h, KNET_SUB_LINK, "Cannot add loopback link when other links are already configured."); err = -1; savederrno = EINVAL; goto exit_unlock; } } } link = &host->link[link_id]; if (link->configured != 0) { err =-1; savederrno = EBUSY; log_err(knet_h, KNET_SUB_LINK, "Host %u link %u is currently configured: %s", host_id, link_id, strerror(savederrno)); goto exit_unlock; } if (link->status.enabled != 0) { err =-1; savederrno = EBUSY; log_err(knet_h, KNET_SUB_LINK, "Host %u link %u is currently in use: %s", host_id, link_id, strerror(savederrno)); goto exit_unlock; } memmove(&link->src_addr, src_addr, sizeof(struct sockaddr_storage)); err = knet_addrtostr(src_addr, sizeof(struct sockaddr_storage), link->status.src_ipaddr, KNET_MAX_HOST_LEN, link->status.src_port, KNET_MAX_PORT_LEN); if (err) { if (err == EAI_SYSTEM) { savederrno = errno; log_warn(knet_h, KNET_SUB_LINK, "Unable to resolve host: %u link: %u source addr/port: %s", host_id, link_id, strerror(savederrno)); } else { savederrno = EINVAL; log_warn(knet_h, KNET_SUB_LINK, "Unable to resolve host: %u link: %u source addr/port: %s", host_id, link_id, gai_strerror(err)); } err = -1; goto exit_unlock; } if (!dst_addr) { link->dynamic = KNET_LINK_DYNIP; } else { link->dynamic = KNET_LINK_STATIC; memmove(&link->dst_addr, dst_addr, sizeof(struct sockaddr_storage)); err = knet_addrtostr(dst_addr, sizeof(struct sockaddr_storage), link->status.dst_ipaddr, KNET_MAX_HOST_LEN, link->status.dst_port, KNET_MAX_PORT_LEN); if (err) { if (err == EAI_SYSTEM) { savederrno = errno; log_warn(knet_h, KNET_SUB_LINK, "Unable to resolve host: %u link: %u destination addr/port: %s", host_id, link_id, strerror(savederrno)); } else { savederrno = EINVAL; log_warn(knet_h, KNET_SUB_LINK, "Unable to resolve host: %u link: %u destination addr/port: %s", host_id, link_id, gai_strerror(err)); } err = -1; goto exit_unlock; } } - link->transport_type = transport; - link->transport_connected = 0; - link->proto_overhead = knet_h->transport_ops[link->transport_type]->transport_mtu_overhead; link->pong_count = KNET_LINK_DEFAULT_PONG_COUNT; link->has_valid_mtu = 0; link->ping_interval = KNET_LINK_DEFAULT_PING_INTERVAL * 1000; /* microseconds */ link->pong_timeout = KNET_LINK_DEFAULT_PING_TIMEOUT * 1000; /* microseconds */ link->latency_fix = KNET_LINK_DEFAULT_PING_PRECISION; link->latency_exp = KNET_LINK_DEFAULT_PING_PRECISION - \ ((link->ping_interval * KNET_LINK_DEFAULT_PING_PRECISION) / 8000000); link->flags = flags; - if (knet_h->transport_ops[link->transport_type]->transport_link_set_config(knet_h, link) < 0) { + if (transport_link_set_config(knet_h, link, transport) < 0) { savederrno = errno; err = -1; goto exit_unlock; } link->configured = 1; log_debug(knet_h, KNET_SUB_LINK, "host: %u link: %u is configured", host_id, link_id); if (transport == KNET_TRANSPORT_LOOPBACK) { knet_h->has_loop_link = 1; knet_h->loop_link = link_id; host->status.reachable = 1; } exit_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_link_get_config(knet_handle_t knet_h, knet_node_id_t host_id, uint8_t link_id, uint8_t *transport, struct sockaddr_storage *src_addr, struct sockaddr_storage *dst_addr, uint8_t *dynamic, uint64_t *flags) { int savederrno = 0, err = 0; struct knet_host *host; struct knet_link *link; if (!knet_h) { errno = EINVAL; return -1; } if (link_id >= KNET_MAX_LINK) { errno = EINVAL; return -1; } if (!src_addr) { errno = EINVAL; return -1; } if (!dynamic) { errno = EINVAL; return -1; } if (!transport) { errno = EINVAL; return -1; } if (!flags) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_LINK, "Unable to get read lock: %s", strerror(savederrno)); errno = savederrno; return -1; } host = knet_h->host_index[host_id]; if (!host) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "Unable to find host %u: %s", host_id, strerror(savederrno)); goto exit_unlock; } link = &host->link[link_id]; if (!link->configured) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "host %u link %u is not configured: %s", host_id, link_id, strerror(savederrno)); goto exit_unlock; } if ((link->dynamic == KNET_LINK_STATIC) && (!dst_addr)) { savederrno = EINVAL; err = -1; goto exit_unlock; } memmove(src_addr, &link->src_addr, sizeof(struct sockaddr_storage)); *transport = link->transport_type; *flags = link->flags; if (link->dynamic == KNET_LINK_STATIC) { *dynamic = 0; memmove(dst_addr, &link->dst_addr, sizeof(struct sockaddr_storage)); } else { *dynamic = 1; } exit_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_link_clear_config(knet_handle_t knet_h, knet_node_id_t host_id, uint8_t link_id) { int savederrno = 0, err = 0; struct knet_host *host; struct knet_link *link; if (!knet_h) { errno = EINVAL; return -1; } if (link_id >= KNET_MAX_LINK) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_LINK, "Unable to get write lock: %s", strerror(savederrno)); errno = savederrno; return -1; } host = knet_h->host_index[host_id]; if (!host) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "Unable to find host %u: %s", host_id, strerror(savederrno)); goto exit_unlock; } link = &host->link[link_id]; if (link->configured != 1) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "Host %u link %u is not configured: %s", host_id, link_id, strerror(savederrno)); goto exit_unlock; } if (link->status.enabled != 0) { err = -1; savederrno = EBUSY; log_err(knet_h, KNET_SUB_LINK, "Host %u link %u is currently in use: %s", host_id, link_id, strerror(savederrno)); goto exit_unlock; } - if ((knet_h->transport_ops[link->transport_type]->transport_link_clear_config(knet_h, link) < 0) && + if ((transport_link_clear_config(knet_h, link) < 0) && (errno != EBUSY)) { savederrno = errno; err = -1; goto exit_unlock; } memset(link, 0, sizeof(struct knet_link)); link->link_id = link_id; if (knet_h->has_loop_link && link_id == knet_h->loop_link) { knet_h->has_loop_link = 0; if (host->active_link_entries == 0) { host->status.reachable = 0; } } log_debug(knet_h, KNET_SUB_LINK, "host: %u link: %u config has been wiped", host_id, link_id); exit_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_link_set_enable(knet_handle_t knet_h, knet_node_id_t host_id, uint8_t link_id, unsigned int enabled) { int savederrno = 0, err = 0; struct knet_host *host; struct knet_link *link; if (!knet_h) { errno = EINVAL; return -1; } if (link_id >= KNET_MAX_LINK) { errno = EINVAL; return -1; } if (enabled > 1) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_LINK, "Unable to get read lock: %s", strerror(savederrno)); errno = savederrno; return -1; } host = knet_h->host_index[host_id]; if (!host) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "Unable to find host %u: %s", host_id, strerror(savederrno)); goto exit_unlock; } link = &host->link[link_id]; if (!link->configured) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "host %u link %u is not configured: %s", host_id, link_id, strerror(savederrno)); goto exit_unlock; } if (link->status.enabled == enabled) { err = 0; goto exit_unlock; } err = _link_updown(knet_h, host_id, link_id, enabled, link->status.connected); savederrno = errno; if (enabled) { goto exit_unlock; } log_debug(knet_h, KNET_SUB_LINK, "host: %u link: %u is disabled", host_id, link_id); exit_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_link_get_enable(knet_handle_t knet_h, knet_node_id_t host_id, uint8_t link_id, unsigned int *enabled) { int savederrno = 0, err = 0; struct knet_host *host; struct knet_link *link; if (!knet_h) { errno = EINVAL; return -1; } if (link_id >= KNET_MAX_LINK) { errno = EINVAL; return -1; } if (!enabled) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_LINK, "Unable to get read lock: %s", strerror(savederrno)); errno = savederrno; return -1; } host = knet_h->host_index[host_id]; if (!host) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "Unable to find host %u: %s", host_id, strerror(savederrno)); goto exit_unlock; } link = &host->link[link_id]; if (!link->configured) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "host %u link %u is not configured: %s", host_id, link_id, strerror(savederrno)); goto exit_unlock; } *enabled = link->status.enabled; exit_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_link_set_pong_count(knet_handle_t knet_h, knet_node_id_t host_id, uint8_t link_id, uint8_t pong_count) { int savederrno = 0, err = 0; struct knet_host *host; struct knet_link *link; if (!knet_h) { errno = EINVAL; return -1; } if (link_id >= KNET_MAX_LINK) { errno = EINVAL; return -1; } if (pong_count < 1) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_LINK, "Unable to get write lock: %s", strerror(savederrno)); errno = savederrno; return -1; } host = knet_h->host_index[host_id]; if (!host) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "Unable to find host %u: %s", host_id, strerror(savederrno)); goto exit_unlock; } link = &host->link[link_id]; if (!link->configured) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "host %u link %u is not configured: %s", host_id, link_id, strerror(savederrno)); goto exit_unlock; } link->pong_count = pong_count; log_debug(knet_h, KNET_SUB_LINK, "host: %u link: %u pong count update: %u", host_id, link_id, link->pong_count); exit_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_link_get_pong_count(knet_handle_t knet_h, knet_node_id_t host_id, uint8_t link_id, uint8_t *pong_count) { int savederrno = 0, err = 0; struct knet_host *host; struct knet_link *link; if (!knet_h) { errno = EINVAL; return -1; } if (link_id >= KNET_MAX_LINK) { errno = EINVAL; return -1; } if (!pong_count) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_LINK, "Unable to get read lock: %s", strerror(savederrno)); errno = savederrno; return -1; } host = knet_h->host_index[host_id]; if (!host) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "Unable to find host %u: %s", host_id, strerror(savederrno)); goto exit_unlock; } link = &host->link[link_id]; if (!link->configured) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "host %u link %u is not configured: %s", host_id, link_id, strerror(savederrno)); goto exit_unlock; } *pong_count = link->pong_count; exit_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_link_set_ping_timers(knet_handle_t knet_h, knet_node_id_t host_id, uint8_t link_id, time_t interval, time_t timeout, unsigned int precision) { int savederrno = 0, err = 0; struct knet_host *host; struct knet_link *link; if (!knet_h) { errno = EINVAL; return -1; } if (link_id >= KNET_MAX_LINK) { errno = EINVAL; return -1; } if (!interval) { errno = EINVAL; return -1; } if (!timeout) { errno = EINVAL; return -1; } if (!precision) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_LINK, "Unable to get write lock: %s", strerror(savederrno)); errno = savederrno; return -1; } host = knet_h->host_index[host_id]; if (!host) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "Unable to find host %u: %s", host_id, strerror(savederrno)); goto exit_unlock; } link = &host->link[link_id]; if (!link->configured) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "host %u link %u is not configured: %s", host_id, link_id, strerror(savederrno)); goto exit_unlock; } link->ping_interval = interval * 1000; /* microseconds */ link->pong_timeout = timeout * 1000; /* microseconds */ link->latency_fix = precision; link->latency_exp = precision - \ ((link->ping_interval * precision) / 8000000); log_debug(knet_h, KNET_SUB_LINK, "host: %u link: %u timeout update - interval: %llu timeout: %llu precision: %u", host_id, link_id, link->ping_interval, link->pong_timeout, precision); exit_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_link_get_ping_timers(knet_handle_t knet_h, knet_node_id_t host_id, uint8_t link_id, time_t *interval, time_t *timeout, unsigned int *precision) { int savederrno = 0, err = 0; struct knet_host *host; struct knet_link *link; if (!knet_h) { errno = EINVAL; return -1; } if (link_id >= KNET_MAX_LINK) { errno = EINVAL; return -1; } if (!interval) { errno = EINVAL; return -1; } if (!timeout) { errno = EINVAL; return -1; } if (!precision) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_LINK, "Unable to get read lock: %s", strerror(savederrno)); errno = savederrno; return -1; } host = knet_h->host_index[host_id]; if (!host) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "Unable to find host %u: %s", host_id, strerror(savederrno)); goto exit_unlock; } link = &host->link[link_id]; if (!link->configured) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "host %u link %u is not configured: %s", host_id, link_id, strerror(savederrno)); goto exit_unlock; } *interval = link->ping_interval / 1000; /* microseconds */ *timeout = link->pong_timeout / 1000; *precision = link->latency_fix; exit_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_link_set_priority(knet_handle_t knet_h, knet_node_id_t host_id, uint8_t link_id, uint8_t priority) { int savederrno = 0, err = 0; struct knet_host *host; struct knet_link *link; uint8_t old_priority; if (!knet_h) { errno = EINVAL; return -1; } if (link_id >= KNET_MAX_LINK) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_LINK, "Unable to get write lock: %s", strerror(savederrno)); errno = savederrno; return -1; } host = knet_h->host_index[host_id]; if (!host) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "Unable to find host %u: %s", host_id, strerror(savederrno)); goto exit_unlock; } link = &host->link[link_id]; if (!link->configured) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "host %u link %u is not configured: %s", host_id, link_id, strerror(savederrno)); goto exit_unlock; } old_priority = link->priority; if (link->priority == priority) { err = 0; goto exit_unlock; } link->priority = priority; if (_host_dstcache_update_sync(knet_h, host)) { savederrno = errno; log_debug(knet_h, KNET_SUB_LINK, "Unable to update link priority (host: %u link: %u priority: %u): %s", host_id, link_id, link->priority, strerror(savederrno)); link->priority = old_priority; err = -1; goto exit_unlock; } log_debug(knet_h, KNET_SUB_LINK, "host: %u link: %u priority set to: %u", host_id, link_id, link->priority); exit_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_link_get_priority(knet_handle_t knet_h, knet_node_id_t host_id, uint8_t link_id, uint8_t *priority) { int savederrno = 0, err = 0; struct knet_host *host; struct knet_link *link; if (!knet_h) { errno = EINVAL; return -1; } if (link_id >= KNET_MAX_LINK) { errno = EINVAL; return -1; } if (!priority) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_LINK, "Unable to get read lock: %s", strerror(savederrno)); errno = savederrno; return -1; } host = knet_h->host_index[host_id]; if (!host) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "Unable to find host %u: %s", host_id, strerror(savederrno)); goto exit_unlock; } link = &host->link[link_id]; if (!link->configured) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "host %u link %u is not configured: %s", host_id, link_id, strerror(savederrno)); goto exit_unlock; } *priority = link->priority; exit_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_link_get_link_list(knet_handle_t knet_h, knet_node_id_t host_id, uint8_t *link_ids, size_t *link_ids_entries) { int savederrno = 0, err = 0, i, count = 0; struct knet_host *host; struct knet_link *link; if (!knet_h) { errno = EINVAL; return -1; } if (!link_ids) { errno = EINVAL; return -1; } if (!link_ids_entries) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_LINK, "Unable to get read lock: %s", strerror(savederrno)); errno = savederrno; return -1; } host = knet_h->host_index[host_id]; if (!host) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "Unable to find host %u: %s", host_id, strerror(savederrno)); goto exit_unlock; } for (i = 0; i < KNET_MAX_LINK; i++) { link = &host->link[i]; if (!link->configured) { continue; } link_ids[count] = i; count++; } *link_ids_entries = count; exit_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } int knet_link_get_status(knet_handle_t knet_h, knet_node_id_t host_id, uint8_t link_id, struct knet_link_status *status, size_t struct_size) { int savederrno = 0, err = 0; struct knet_host *host; struct knet_link *link; if (!knet_h) { errno = EINVAL; return -1; } if (link_id >= KNET_MAX_LINK) { errno = EINVAL; return -1; } if (!status) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_LINK, "Unable to get read lock: %s", strerror(savederrno)); errno = savederrno; return -1; } host = knet_h->host_index[host_id]; if (!host) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "Unable to find host %u: %s", host_id, strerror(savederrno)); goto exit_unlock; } link = &host->link[link_id]; if (!link->configured) { err = -1; savederrno = EINVAL; log_err(knet_h, KNET_SUB_LINK, "host %u link %u is not configured: %s", host_id, link_id, strerror(savederrno)); goto exit_unlock; } memmove(status, &link->status, struct_size); /* Calculate totals - no point in doing this on-the-fly */ status->stats.rx_total_packets = status->stats.rx_data_packets + status->stats.rx_ping_packets + status->stats.rx_pong_packets + status->stats.rx_pmtu_packets; status->stats.tx_total_packets = status->stats.tx_data_packets + status->stats.tx_ping_packets + status->stats.tx_pong_packets + status->stats.tx_pmtu_packets; status->stats.rx_total_bytes = status->stats.rx_data_bytes + status->stats.rx_ping_bytes + status->stats.rx_pong_bytes + status->stats.rx_pmtu_bytes; status->stats.tx_total_bytes = status->stats.tx_data_bytes + status->stats.tx_ping_bytes + status->stats.tx_pong_bytes + status->stats.tx_pmtu_bytes; status->stats.tx_total_errors = status->stats.tx_data_errors + status->stats.tx_ping_errors + status->stats.tx_pong_errors + status->stats.tx_pmtu_errors; status->stats.tx_total_retries = status->stats.tx_data_retries + status->stats.tx_ping_retries + status->stats.tx_pong_retries + status->stats.tx_pmtu_retries; /* Tell the caller our full size in case they have an old version */ status->size = sizeof(struct knet_link_status); exit_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } diff --git a/libknet/tests/knet_bench.c b/libknet/tests/knet_bench.c index a26637eb..477b7357 100644 --- a/libknet/tests/knet_bench.c +++ b/libknet/tests/knet_bench.c @@ -1,1026 +1,1026 @@ /* * Copyright (C) 2016-2017 Red Hat, Inc. All rights reserved. * * Authors: Fabio M. Di Nitto * * This software licensed under GPL-2.0+, LGPL-2.0+ */ #include "config.h" #include #include #include #include #include #include #include #include #include #include "libknet.h" #include "compat.h" #include "internals.h" #include "netutils.h" -#include "transports.h" +#include "transport_common.h" #include "threads_common.h" #include "test-common.h" #define MAX_NODES 128 static int senderid = -1; static int thisnodeid = -1; static knet_handle_t knet_h; static int datafd = 0; static int8_t channel = 0; static int globallistener = 0; static int continous = 0; static struct sockaddr_storage allv4; static struct sockaddr_storage allv6; static int broadcast_test = 1; static pthread_t rx_thread = (pthread_t)NULL; static char *rx_buf[PCKT_FRAG_MAX]; static int wait_for_perf_rx = 0; static char *compresscfg = NULL; static int bench_shutdown_in_progress = 0; static pthread_mutex_t shutdown_mutex = PTHREAD_MUTEX_INITIALIZER; #define TEST_PING 0 #define TEST_PING_AND_DATA 1 #define TEST_PERF_BY_SIZE 2 #define TEST_PERF_BY_TIME 3 static int test_type = TEST_PING; #define TEST_START 2 #define TEST_STOP 4 #define TEST_COMPLETE 6 #define ONE_GIGABYTE 1073741824 static uint64_t perf_by_size_size = 1 * ONE_GIGABYTE; static uint64_t perf_by_time_secs = 10; struct node { int nodeid; int links; struct sockaddr_storage address[KNET_MAX_LINK]; }; static void print_help(void) { printf("knet_bench usage:\n"); printf(" -h print this help (no really)\n"); printf(" -d enable debug logs (default INFO)\n"); printf(" -c [implementation]:[crypto]:[hashing] crypto configuration. (default disabled)\n"); printf(" Example: -c nss:aes128:sha1\n"); printf(" -z [implementation]:[level]:[threshold] compress configuration. (default disabled)\n"); printf(" Example: -z zlib:5:100\n"); printf(" -p [active|passive|rr] (default: passive)\n"); printf(" -P [udp|sctp] (default: udp) protocol (transport) to use\n"); printf(" -t [nodeid] This nodeid (required)\n"); printf(" -n [nodeid],[link1_ip_addr],[link2_..] Other nodes information (at least one required)\n"); printf(" Example: -t 1,192.168.8.1,3ffe::8:1,..\n"); printf(" can be repeated up to %d and should contain also the localnode info\n", MAX_NODES); printf(" -b [port] baseport (default: 50000)\n"); printf(" -l enable global listener on 0.0.0.0/:: (default: off, incompatible with -o)\n"); printf(" -o enable baseport offset per nodeid\n"); printf(" -w dont wait for all nodes to be up before starting the test (default: wait)\n"); printf(" -T [ping|ping_data|perf-by-size|perf-by-time]\n"); printf(" test type (default: ping)\n"); printf(" ping: will wait for all hosts to join the knet network, sleep 5 seconds and quit\n"); printf(" ping_data: will wait for all hosts to join the knet network, sends some data to all nodes and quit\n"); printf(" perf-by-size: will wait for all hosts to join the knet network,\n"); printf(" perform a series of benchmarks by transmitting a known\n"); printf(" size/quantity of packets and measuring the time, then quit\n"); printf(" perf-by-time: will wait for all hosts to join the knet network,\n"); printf(" perform a series of benchmarks by transmitting a known\n"); printf(" size of packets for a given amount of time (10 seconds)\n"); printf(" and measuring the quantity of data transmitted, then quit\n"); printf(" -s nodeid that will generate traffic for benchmarks\n"); printf(" -S [size|seconds] when used in combination with -T perf-by-size it indicates how many GB of traffic to generate for the test. (default: 1GB)\n"); printf(" when used in combination with -T perf-by-time it indicates how many Seconds of traffic to generate for the test. (default: 10 seconds)\n"); printf(" -C repeat the test continously (default: off)\n"); } static void parse_nodes(char *nodesinfo[MAX_NODES], int onidx, int port, struct node nodes[MAX_NODES], int *thisidx) { int i; char *temp = NULL; char port_str[10]; memset(port_str, 0, sizeof(port_str)); sprintf(port_str, "%d", port); for (i = 0; i < onidx; i++) { nodes[i].nodeid = atoi(strtok(nodesinfo[i], ",")); if ((nodes[i].nodeid < 0) || (nodes[i].nodeid > KNET_MAX_HOST)) { printf("Invalid nodeid: %d (0 - %d)\n", nodes[i].nodeid, KNET_MAX_HOST); exit(FAIL); } if (thisnodeid == nodes[i].nodeid) { *thisidx = i; } while((temp = strtok(NULL, ","))) { if (nodes[i].links == KNET_MAX_LINK) { printf("Too many links configured. Max %d\n", KNET_MAX_LINK); exit(FAIL); } if (knet_strtoaddr(temp, port_str, &nodes[i].address[nodes[i].links], sizeof(struct sockaddr_storage)) < 0) { printf("Unable to convert %s to sockaddress\n", temp); exit(FAIL); } nodes[i].links++; } } if (knet_strtoaddr("0.0.0.0", port_str, &allv4, sizeof(struct sockaddr_storage)) < 0) { printf("Unable to convert 0.0.0.0 to sockaddress\n"); exit(FAIL); } if (knet_strtoaddr("::", port_str, &allv6, sizeof(struct sockaddr_storage)) < 0) { printf("Unable to convert :: to sockaddress\n"); exit(FAIL); } for (i = 1; i < onidx; i++) { if (nodes[0].links != nodes[i].links) { printf("knet_bench does not support unbalanced link configuration\n"); exit(FAIL); } } return; } static int private_data; static void sock_notify(void *pvt_data, int local_datafd, int8_t local_channel, uint8_t tx_rx, int error, int errorno) { printf("Error (%d - %d - %s) from socket: %d\n", error, errorno, strerror(errno), local_datafd); return; } static int ping_dst_host_filter(void *pvt_data, const unsigned char *outdata, ssize_t outdata_len, uint8_t tx_rx, knet_node_id_t this_host_id, knet_node_id_t src_host_id, int8_t *dst_channel, knet_node_id_t *dst_host_ids, size_t *dst_host_ids_entries) { if (broadcast_test) { return 1; } if (tx_rx == KNET_NOTIFY_TX) { memmove(&dst_host_ids[0], outdata, 2); } else { dst_host_ids[0] = this_host_id; } *dst_host_ids_entries = 1; return 0; } static void setup_knet(int argc, char *argv[]) { int logfd; int rv; char *cryptocfg = NULL, *policystr = NULL, *protostr = NULL; char *othernodeinfo[MAX_NODES]; struct node nodes[MAX_NODES]; int thisidx = -1; int onidx = 0; int debug = KNET_LOG_INFO; int port = 50000, portoffset = 0; int thisport = 0, otherport = 0; int thisnewport = 0, othernewport = 0; struct sockaddr_in *so_in; struct sockaddr_in6 *so_in6; struct sockaddr_storage *src; int i, link_idx, allnodesup = 0; int policy = KNET_LINK_POLICY_PASSIVE, policyfound = 0; int protocol = KNET_TRANSPORT_UDP, protofound = 0; int wait = 1; struct knet_handle_crypto_cfg knet_handle_crypto_cfg; char *cryptomodel = NULL, *cryptotype = NULL, *cryptohash = NULL; struct knet_handle_compress_cfg knet_handle_compress_cfg; memset(nodes, 0, sizeof(nodes)); while ((rv = getopt(argc, argv, "CT:S:s:ldowb:t:n:c:p:P:z:h")) != EOF) { switch(rv) { case 'h': print_help(); exit(PASS); break; case 'd': debug = KNET_LOG_DEBUG; break; case 'c': if (cryptocfg) { printf("Error: -c can only be specified once\n"); exit(FAIL); } cryptocfg = optarg; break; case 'p': if (policystr) { printf("Error: -p can only be specified once\n"); exit(FAIL); } policystr = optarg; if (!strcmp(policystr, "active")) { policy = KNET_LINK_POLICY_ACTIVE; policyfound = 1; } /* * we can't use rr because clangs can't compile * an array of 3 strings, one of which is 2 bytes long */ if (!strcmp(policystr, "round-robin")) { policy = KNET_LINK_POLICY_RR; policyfound = 1; } if (!strcmp(policystr, "passive")) { policy = KNET_LINK_POLICY_PASSIVE; policyfound = 1; } if (!policyfound) { printf("Error: invalid policy %s specified. -p accepts active|passive|rr\n", policystr); exit(FAIL); } break; case 'P': if (protostr) { printf("Error: -P can only be specified once\n"); exit(FAIL); } protostr = optarg; if (!strcmp(protostr, "udp")) { protocol = KNET_TRANSPORT_UDP; protofound = 1; } if (!strcmp(protostr, "sctp")) { protocol = KNET_TRANSPORT_SCTP; protofound = 1; } if (!protofound) { printf("Error: invalid protocol %s specified. -P accepts udp|sctp\n", policystr); exit(FAIL); } break; case 't': if (thisnodeid >= 0) { printf("Error: -t can only be specified once\n"); exit(FAIL); } thisnodeid = atoi(optarg); if ((thisnodeid < 0) || (thisnodeid > 65536)) { printf("Error: -t nodeid out of range %d (1 - 65536)\n", thisnodeid); exit(FAIL); } break; case 'n': if (onidx == MAX_NODES) { printf("Error: too many other nodes. Max %d\n", MAX_NODES); exit(FAIL); } othernodeinfo[onidx] = optarg; onidx++; break; case 'b': port = atoi(optarg); if ((port < 1) || (port > 65536)) { printf("Error: port %d out of range (1 - 65536)\n", port); exit(FAIL); } break; case 'o': if (globallistener) { printf("Error: -l cannot be used with -o\n"); exit(FAIL); } portoffset = 1; break; case 'l': if (portoffset) { printf("Error: -o cannot be used with -l\n"); exit(FAIL); } globallistener = 1; break; case 'w': wait = 0; break; case 's': if (senderid >= 0) { printf("Error: -s can only be specified once\n"); exit(FAIL); } senderid = atoi(optarg); if ((senderid < 0) || (senderid > 65536)) { printf("Error: -s nodeid out of range %d (1 - 65536)\n", senderid); exit(FAIL); } break; case 'T': if (!strcmp("ping", optarg)) { test_type = TEST_PING; } if (!strcmp("ping_data", optarg)) { test_type = TEST_PING_AND_DATA; } if (!strcmp("perf-by-size", optarg)) { test_type = TEST_PERF_BY_SIZE; } if (!strcmp("perf-by-time", optarg)) { test_type = TEST_PERF_BY_TIME; } break; case 'S': perf_by_size_size = (uint64_t)atoi(optarg) * ONE_GIGABYTE; perf_by_time_secs = (uint64_t)atoi(optarg); break; case 'C': continous = 1; break; case 'z': if (compresscfg) { printf("Error: -c can only be specified once\n"); exit(FAIL); } compresscfg = optarg; break; default: break; } } if (thisnodeid < 0) { printf("Who am I?!? missing -t from command line?\n"); exit(FAIL); } if (onidx < 1) { printf("no other nodes configured?!? missing -n from command line\n"); exit(FAIL); } parse_nodes(othernodeinfo, onidx, port, nodes, &thisidx); if (thisidx < 0) { printf("no config for this node found\n"); exit(FAIL); } if (senderid >= 0) { for (i=0; i < onidx; i++) { if (senderid == nodes[i].nodeid) { break; } } if (i == onidx) { printf("Unable to find senderid in nodelist\n"); exit(FAIL); } } if (((test_type == TEST_PERF_BY_SIZE) || (test_type == TEST_PERF_BY_TIME)) && (senderid < 0)) { printf("Error: performance test requires -s to be set (for now)\n"); exit(FAIL); } logfd = start_logging(stdout); knet_h = knet_handle_new(thisnodeid, logfd, debug); if (!knet_h) { printf("Unable to knet_handle_new: %s\n", strerror(errno)); exit(FAIL); } if (cryptocfg) { memset(&knet_handle_crypto_cfg, 0, sizeof(knet_handle_crypto_cfg)); cryptomodel = strtok(cryptocfg, ":"); cryptotype = strtok(NULL, ":"); cryptohash = strtok(NULL, ":"); if (cryptomodel) { strncpy(knet_handle_crypto_cfg.crypto_model, cryptomodel, sizeof(knet_handle_crypto_cfg.crypto_model) - 1); } if (cryptotype) { strncpy(knet_handle_crypto_cfg.crypto_cipher_type, cryptotype, sizeof(knet_handle_crypto_cfg.crypto_cipher_type) - 1); } if (cryptohash) { strncpy(knet_handle_crypto_cfg.crypto_hash_type, cryptohash, sizeof(knet_handle_crypto_cfg.crypto_hash_type) - 1); } knet_handle_crypto_cfg.private_key_len = KNET_MAX_KEY_LEN; if (knet_handle_crypto(knet_h, &knet_handle_crypto_cfg)) { printf("Unable to init crypto\n"); exit(FAIL); } } if (compresscfg) { memset(&knet_handle_compress_cfg, 0, sizeof(struct knet_handle_compress_cfg)); snprintf(knet_handle_compress_cfg.compress_model, 16, "%s", strtok(compresscfg, ":")); knet_handle_compress_cfg.compress_level = atoi(strtok(NULL, ":")); knet_handle_compress_cfg.compress_threshold = atoi(strtok(NULL, ":")); if (knet_handle_compress(knet_h, &knet_handle_compress_cfg)) { printf("Unable to configure compress\n"); exit(FAIL); } } if (knet_handle_enable_sock_notify(knet_h, &private_data, sock_notify) < 0) { printf("knet_handle_enable_sock_notify failed: %s\n", strerror(errno)); knet_handle_free(knet_h); exit(FAIL); } datafd = 0; channel = -1; if (knet_handle_add_datafd(knet_h, &datafd, &channel) < 0) { printf("knet_handle_add_datafd failed: %s\n", strerror(errno)); knet_handle_free(knet_h); exit(FAIL); } if (knet_handle_pmtud_setfreq(knet_h, 60) < 0) { printf("knet_handle_pmtud_setfreq failed: %s\n", strerror(errno)); knet_handle_free(knet_h); exit(FAIL); } for (i=0; i < onidx; i++) { if (i == thisidx) { continue; } if (knet_host_add(knet_h, nodes[i].nodeid) < 0) { printf("knet_host_add failed: %s\n", strerror(errno)); exit(FAIL); } if (knet_host_set_policy(knet_h, nodes[i].nodeid, policy) < 0) { printf("knet_host_set_policy failed: %s\n", strerror(errno)); exit(FAIL); } for (link_idx = 0; link_idx < nodes[i].links; link_idx++) { if (portoffset) { if (nodes[thisidx].address[link_idx].ss_family == AF_INET) { so_in = (struct sockaddr_in *)&nodes[thisidx].address[link_idx]; thisport = ntohs(so_in->sin_port); thisnewport = thisport + nodes[i].nodeid; so_in->sin_port = (htons(thisnewport)); so_in = (struct sockaddr_in *)&nodes[i].address[link_idx]; otherport = ntohs(so_in->sin_port); othernewport = otherport + nodes[thisidx].nodeid; so_in->sin_port = (htons(othernewport)); } else { so_in6 = (struct sockaddr_in6 *)&nodes[thisidx].address[link_idx]; thisport = ntohs(so_in6->sin6_port); thisnewport = thisport + nodes[i].nodeid; so_in6->sin6_port = (htons(thisnewport)); so_in6 = (struct sockaddr_in6 *)&nodes[i].address[link_idx]; otherport = ntohs(so_in6->sin6_port); othernewport = otherport + nodes[thisidx].nodeid; so_in6->sin6_port = (htons(othernewport)); } } if (!globallistener) { src = &nodes[thisidx].address[link_idx]; } else { if (nodes[thisidx].address[link_idx].ss_family == AF_INET) { src = &allv4; } else { src = &allv6; } } if (knet_link_set_config(knet_h, nodes[i].nodeid, link_idx, protocol, src, &nodes[i].address[link_idx], 0) < 0) { printf("Unable to configure link: %s\n", strerror(errno)); exit(FAIL); } if (portoffset) { if (nodes[thisidx].address[link_idx].ss_family == AF_INET) { so_in = (struct sockaddr_in *)&nodes[thisidx].address[link_idx]; so_in->sin_port = (htons(thisport)); so_in = (struct sockaddr_in *)&nodes[i].address[link_idx]; so_in->sin_port = (htons(otherport)); } else { so_in6 = (struct sockaddr_in6 *)&nodes[thisidx].address[link_idx]; so_in6->sin6_port = (htons(thisport)); so_in6 = (struct sockaddr_in6 *)&nodes[i].address[link_idx]; so_in6->sin6_port = (htons(otherport)); } } if (knet_link_set_enable(knet_h, nodes[i].nodeid, link_idx, 1) < 0) { printf("knet_link_set_enable failed: %s\n", strerror(errno)); exit(FAIL); } if (knet_link_set_ping_timers(knet_h, nodes[i].nodeid, link_idx, 1000, 10000, 2048) < 0) { printf("knet_link_set_ping_timers failed: %s\n", strerror(errno)); exit(FAIL); } if (knet_link_set_pong_count(knet_h, nodes[i].nodeid, link_idx, 2) < 0) { printf("knet_link_set_pong_count failed: %s\n", strerror(errno)); exit(FAIL); } } } if (knet_handle_enable_filter(knet_h, NULL, ping_dst_host_filter)) { printf("Unable to enable dst_host_filter: %s\n", strerror(errno)); exit(FAIL); } if (knet_handle_setfwd(knet_h, 1) < 0) { printf("knet_handle_setfwd failed: %s\n", strerror(errno)); exit(FAIL); } if (wait) { while(!allnodesup) { allnodesup = 1; for (i=0; i < onidx; i++) { if (i == thisidx) { continue; } if(knet_h->host_index[nodes[i].nodeid]->status.reachable != 1) { printf("waiting host %d to be reachable\n", nodes[i].nodeid); allnodesup = 0; } } if (!allnodesup) { sleep(1); } } sleep(1); } } static void *_rx_thread(void *args) { int rx_epoll; struct epoll_event ev; struct epoll_event events[KNET_EPOLL_MAX_EVENTS]; struct sockaddr_storage address[PCKT_FRAG_MAX]; struct knet_mmsghdr msg[PCKT_FRAG_MAX]; struct iovec iov_in[PCKT_FRAG_MAX]; int i, msg_recv; struct timespec clock_start, clock_end; unsigned long long time_diff = 0; uint64_t rx_pkts = 0; uint64_t rx_bytes = 0; unsigned int current_pckt_size = 0; for (i = 0; i < PCKT_FRAG_MAX; i++) { rx_buf[i] = malloc(KNET_MAX_PACKET_SIZE); if (!rx_buf[i]) { printf("RXT: Unable to malloc!\n"); return NULL; } memset(rx_buf[i], 0, KNET_MAX_PACKET_SIZE); iov_in[i].iov_base = (void *)rx_buf[i]; iov_in[i].iov_len = KNET_MAX_PACKET_SIZE; memset(&msg[i].msg_hdr, 0, sizeof(struct msghdr)); msg[i].msg_hdr.msg_name = &address[i]; msg[i].msg_hdr.msg_namelen = sizeof(struct sockaddr_storage); msg[i].msg_hdr.msg_iov = &iov_in[i]; msg[i].msg_hdr.msg_iovlen = 1; } rx_epoll = epoll_create(KNET_EPOLL_MAX_EVENTS + 1); if (rx_epoll < 0) { printf("RXT: Unable to create epoll!\nHALTING RX THREAD!\n"); return NULL; } memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLIN; ev.data.fd = datafd; if (epoll_ctl(rx_epoll, EPOLL_CTL_ADD, datafd, &ev)) { printf("RXT: Unable to add datafd to epoll\nHALTING RX THREAD!\n"); return NULL; } memset(&clock_start, 0, sizeof(clock_start)); memset(&clock_end, 0, sizeof(clock_start)); while (!bench_shutdown_in_progress) { if (epoll_wait(rx_epoll, events, KNET_EPOLL_MAX_EVENTS, 1) >= 1) { msg_recv = _recvmmsg(datafd, &msg[0], PCKT_FRAG_MAX, MSG_DONTWAIT | MSG_NOSIGNAL); if (msg_recv < 0) { printf("RXT: error from recvmmsg: %s\n", strerror(errno)); } switch(test_type) { case TEST_PING_AND_DATA: for (i = 0; i < msg_recv; i++) { if (msg[i].msg_len == 0) { printf("RXT: received 0 bytes message?\n"); } printf("received %u bytes message: %s\n", msg[i].msg_len, (char *)msg[i].msg_hdr.msg_iov->iov_base); } break; case TEST_PERF_BY_TIME: case TEST_PERF_BY_SIZE: for (i = 0; i < msg_recv; i++) { if (msg[i].msg_len < 64) { if (msg[i].msg_len == 0) { printf("RXT: received 0 bytes message?\n"); } if (msg[i].msg_len == TEST_START) { if (clock_gettime(CLOCK_MONOTONIC, &clock_start) != 0) { printf("Unable to get start time!\n"); } } if (msg[i].msg_len == TEST_STOP) { double average_rx_mbytes; double average_rx_pkts; double time_diff_sec; if (clock_gettime(CLOCK_MONOTONIC, &clock_end) != 0) { printf("Unable to get end time!\n"); } timespec_diff(clock_start, clock_end, &time_diff); /* * adjust for sleep(2) between sending the last data and TEST_STOP */ time_diff = time_diff - 2000000000llu; /* * convert to seconds */ time_diff_sec = (double)time_diff / 1000000000llu; average_rx_mbytes = (double)((rx_bytes / time_diff_sec) / (1024 * 1024)); average_rx_pkts = (double)(rx_pkts / time_diff_sec); printf("Execution time: %8.4f secs Average speed: %8.4f MB/sec %8.4f pckts/sec (size: %u total: %" PRIu64 ")\n", time_diff_sec, average_rx_mbytes, average_rx_pkts, current_pckt_size, rx_pkts); rx_pkts = 0; rx_bytes = 0; current_pckt_size = 0; } if (msg[i].msg_len == TEST_COMPLETE) { wait_for_perf_rx = 1; } continue; } rx_pkts++; rx_bytes = rx_bytes + msg[i].msg_len; current_pckt_size = msg[i].msg_len; } break; } } } epoll_ctl(rx_epoll, EPOLL_CTL_DEL, datafd, &ev); close(rx_epoll); return NULL; } static void setup_data_txrx_common(void) { if (!rx_thread) { if (knet_handle_enable_filter(knet_h, NULL, ping_dst_host_filter)) { printf("Unable to enable dst_host_filter: %s\n", strerror(errno)); exit(FAIL); } printf("Setting up rx thread\n"); if (pthread_create(&rx_thread, 0, _rx_thread, NULL)) { printf("Unable to start rx thread\n"); exit(FAIL); } } } static void stop_rx_thread(void) { void *retval; int i; if (rx_thread) { printf("Shutting down rx thread\n"); sleep(2); pthread_cancel(rx_thread); pthread_join(rx_thread, &retval); for (i = 0; i < PCKT_FRAG_MAX; i ++) { free(rx_buf[i]); } } } static void send_ping_data(void) { char buf[65535]; ssize_t len; memset(&buf, 0, sizeof(buf)); snprintf(buf, sizeof(buf), "Hello world!"); if (compresscfg) { len = sizeof(buf); } else { len = strlen(buf); } if (knet_send(knet_h, buf, len, channel) != len) { printf("Error sending hello world: %s\n", strerror(errno)); } sleep(1); } static int send_messages(struct knet_mmsghdr *msg, int msgs_to_send) { int sent_msgs, prev_sent, progress, total_sent; total_sent = 0; sent_msgs = 0; prev_sent = 0; progress = 1; retry: errno = 0; sent_msgs = _sendmmsg(datafd, &msg[0], msgs_to_send, MSG_NOSIGNAL); if (sent_msgs < 0) { if ((errno == EAGAIN) || (errno == EWOULDBLOCK)) { usleep(KNET_THREADS_TIMERES / 16); goto retry; } printf("Unable to send messages: %s\n", strerror(errno)); return -1; } total_sent = total_sent + sent_msgs; if ((sent_msgs >= 0) && (sent_msgs < msgs_to_send)) { if ((sent_msgs) || (progress)) { msgs_to_send = msgs_to_send - sent_msgs; prev_sent = prev_sent + sent_msgs; if (sent_msgs) { progress = 1; } else { progress = 0; } goto retry; } if (!progress) { printf("Unable to send more messages after retry\n"); } } return total_sent; } static int setup_send_buffers_common(struct knet_mmsghdr *msg, struct iovec *iov_out, char *tx_buf[]) { int i; for (i = 0; i < PCKT_FRAG_MAX; i++) { tx_buf[i] = malloc(KNET_MAX_PACKET_SIZE); if (!tx_buf[i]) { printf("TXT: Unable to malloc!\n"); return -1; } memset(tx_buf[i], 0, KNET_MAX_PACKET_SIZE); iov_out[i].iov_base = (void *)tx_buf[i]; memset(&msg[i].msg_hdr, 0, sizeof(struct msghdr)); msg[i].msg_hdr.msg_iov = &iov_out[i]; msg[i].msg_hdr.msg_iovlen = 1; } return 0; } static void send_perf_data_by_size(void) { char *tx_buf[PCKT_FRAG_MAX]; struct knet_mmsghdr msg[PCKT_FRAG_MAX]; struct iovec iov_out[PCKT_FRAG_MAX]; char ctrl_message[16]; int sent_msgs; int i; uint64_t total_pkts_to_tx; uint64_t packets_to_send; uint32_t packetsize = 64; setup_send_buffers_common(msg, iov_out, tx_buf); while (packetsize <= KNET_MAX_PACKET_SIZE) { for (i = 0; i < PCKT_FRAG_MAX; i++) { iov_out[i].iov_len = packetsize; } total_pkts_to_tx = perf_by_size_size / packetsize; printf("Testing with %u packet size. Total bytes to transfer: %" PRIu64 " (%" PRIu64 " packets)\n", packetsize, perf_by_size_size, total_pkts_to_tx); memset(ctrl_message, 0, sizeof(ctrl_message)); knet_send(knet_h, ctrl_message, TEST_START, channel); while (total_pkts_to_tx > 0) { if (total_pkts_to_tx >= PCKT_FRAG_MAX) { packets_to_send = PCKT_FRAG_MAX; } else { packets_to_send = total_pkts_to_tx; } sent_msgs = send_messages(&msg[0], packets_to_send); if (sent_msgs < 0) { printf("Something went wrong, aborting\n"); exit(FAIL); } total_pkts_to_tx = total_pkts_to_tx - sent_msgs; } sleep(2); knet_send(knet_h, ctrl_message, TEST_STOP, channel); if (packetsize == KNET_MAX_PACKET_SIZE) { break; } /* * Use a multiplier that can always divide properly a GB * into smaller chunks without worry about boundaries */ packetsize *= 4; if (packetsize > KNET_MAX_PACKET_SIZE) { packetsize = KNET_MAX_PACKET_SIZE; } } knet_send(knet_h, ctrl_message, TEST_COMPLETE, channel); for (i = 0; i < PCKT_FRAG_MAX; i++) { free(tx_buf[i]); } } static void send_perf_data_by_time(void) { char *tx_buf[PCKT_FRAG_MAX]; struct knet_mmsghdr msg[PCKT_FRAG_MAX]; struct iovec iov_out[PCKT_FRAG_MAX]; char ctrl_message[16]; int sent_msgs; int i; uint32_t packetsize = 65536; struct timespec clock_start, clock_end; unsigned long long time_diff = 0; setup_send_buffers_common(msg, iov_out, tx_buf); memset(&clock_start, 0, sizeof(clock_start)); memset(&clock_end, 0, sizeof(clock_start)); while (packetsize <= KNET_MAX_PACKET_SIZE) { for (i = 0; i < PCKT_FRAG_MAX; i++) { iov_out[i].iov_len = packetsize; } printf("Testing with %u bytes packet size for %" PRIu64 " seconds.\n", packetsize, perf_by_time_secs); memset(ctrl_message, 0, sizeof(ctrl_message)); knet_send(knet_h, ctrl_message, TEST_START, channel); if (clock_gettime(CLOCK_MONOTONIC, &clock_start) != 0) { printf("Unable to get start time!\n"); } time_diff = 0; while (time_diff < (perf_by_time_secs * 1000000000llu)) { sent_msgs = send_messages(&msg[0], PCKT_FRAG_MAX); if (sent_msgs < 0) { printf("Something went wrong, aborting\n"); exit(FAIL); } if (clock_gettime(CLOCK_MONOTONIC, &clock_end) != 0) { printf("Unable to get end time!\n"); } timespec_diff(clock_start, clock_end, &time_diff); } sleep(2); knet_send(knet_h, ctrl_message, TEST_STOP, channel); if (packetsize == KNET_MAX_PACKET_SIZE) { break; } /* * Use a multiplier that can always divide properly a GB * into smaller chunks without worry about boundaries */ packetsize *= 4; if (packetsize > KNET_MAX_PACKET_SIZE) { packetsize = KNET_MAX_PACKET_SIZE; } } knet_send(knet_h, ctrl_message, TEST_COMPLETE, channel); for (i = 0; i < PCKT_FRAG_MAX; i++) { free(tx_buf[i]); } } static void cleanup_all(void) { if (pthread_mutex_lock(&shutdown_mutex)) { return; } if (bench_shutdown_in_progress) { pthread_mutex_unlock(&shutdown_mutex); return; } bench_shutdown_in_progress = 1; pthread_mutex_unlock(&shutdown_mutex); if (rx_thread) { stop_rx_thread(); } knet_handle_stop(knet_h); } static void sigint_handler(int signum) { printf("Cleaning up... got signal: %d\n", signum); cleanup_all(); exit(PASS); } int main(int argc, char *argv[]) { if (signal(SIGINT, sigint_handler) == SIG_ERR) { printf("Unable to configure SIGINT handler\n"); exit(FAIL); } need_root(); setup_knet(argc, argv); setup_data_txrx_common(); sleep(5); restart: switch(test_type) { default: case TEST_PING: /* basic ping, no data */ sleep(5); break; case TEST_PING_AND_DATA: send_ping_data(); break; case TEST_PERF_BY_SIZE: if (senderid == thisnodeid) { send_perf_data_by_size(); } else { printf("Waiting for perf rx thread to finish\n"); while(!wait_for_perf_rx) { sleep(1); } } break; case TEST_PERF_BY_TIME: if (senderid == thisnodeid) { send_perf_data_by_time(); } else { printf("Waiting for perf rx thread to finish\n"); while(!wait_for_perf_rx) { sleep(1); } } break; } if (continous) { goto restart; } cleanup_all(); return PASS; } diff --git a/libknet/threads_heartbeat.c b/libknet/threads_heartbeat.c index a5122590..bc684025 100644 --- a/libknet/threads_heartbeat.c +++ b/libknet/threads_heartbeat.c @@ -1,173 +1,174 @@ /* * Copyright (C) 2015-2017 Red Hat, Inc. All rights reserved. * * Authors: Fabio M. Di Nitto * Federico Simoncelli * * This software licensed under GPL-2.0+, LGPL-2.0+ */ #include "config.h" #include #include #include #include #include #include "crypto.h" #include "links.h" #include "logging.h" +#include "transports.h" #include "threads_common.h" #include "threads_heartbeat.h" static void _link_down(knet_handle_t knet_h, struct knet_host *dst_host, struct knet_link *dst_link) { memset(&dst_link->pmtud_last, 0, sizeof(struct timespec)); dst_link->received_pong = 0; dst_link->status.pong_last.tv_nsec = 0; if (dst_link->status.connected == 1) { log_info(knet_h, KNET_SUB_LINK, "host: %u link: %u is down", dst_host->host_id, dst_link->link_id); _link_updown(knet_h, dst_host->host_id, dst_link->link_id, dst_link->status.enabled, 0); } } static void _handle_check_each(knet_handle_t knet_h, struct knet_host *dst_host, struct knet_link *dst_link, int timed) { int err = 0, savederrno = 0; int len; ssize_t outlen = KNET_HEADER_PING_SIZE; struct timespec clock_now, pong_last; unsigned long long diff_ping; unsigned char *outbuf = (unsigned char *)knet_h->pingbuf; if (dst_link->transport_connected == 0) { _link_down(knet_h, dst_host, dst_link); return; } /* caching last pong to avoid race conditions */ pong_last = dst_link->status.pong_last; if (clock_gettime(CLOCK_MONOTONIC, &clock_now) != 0) { log_debug(knet_h, KNET_SUB_HEARTBEAT, "Unable to get monotonic clock"); return; } timespec_diff(dst_link->ping_last, clock_now, &diff_ping); if ((diff_ping >= (dst_link->ping_interval * 1000llu)) || (!timed)) { memmove(&knet_h->pingbuf->khp_ping_time[0], &clock_now, sizeof(struct timespec)); knet_h->pingbuf->khp_ping_link = dst_link->link_id; if (pthread_mutex_lock(&knet_h->tx_seq_num_mutex)) { log_debug(knet_h, KNET_SUB_HEARTBEAT, "Unable to get seq mutex lock"); return; } knet_h->pingbuf->khp_ping_seq_num = htons(knet_h->tx_seq_num); pthread_mutex_unlock(&knet_h->tx_seq_num_mutex); knet_h->pingbuf->khp_ping_timed = timed; if (knet_h->crypto_instance) { if (crypto_encrypt_and_sign(knet_h, (const unsigned char *)knet_h->pingbuf, outlen, knet_h->pingbuf_crypt, &outlen) < 0) { log_debug(knet_h, KNET_SUB_HEARTBEAT, "Unable to crypto ping packet"); return; } outbuf = knet_h->pingbuf_crypt; } retry: len = sendto(dst_link->outsock, outbuf, outlen, MSG_DONTWAIT | MSG_NOSIGNAL, (struct sockaddr *) &dst_link->dst_addr, sizeof(struct sockaddr_storage)); savederrno = errno; dst_link->ping_last = clock_now; dst_link->status.stats.tx_ping_packets++; dst_link->status.stats.tx_ping_bytes += outlen; if (len != outlen) { - err = knet_h->transport_ops[dst_link->transport_type]->transport_tx_sock_error(knet_h, dst_link->outsock, len, savederrno); + err = transport_tx_sock_error(knet_h, dst_link->transport_type, dst_link->outsock, len, savederrno); switch(err) { case -1: /* unrecoverable error */ log_debug(knet_h, KNET_SUB_HEARTBEAT, "Unable to send ping (sock: %d) packet (sendto): %d %s. recorded src ip: %s src port: %s dst ip: %s dst port: %s", dst_link->outsock, savederrno, strerror(savederrno), dst_link->status.src_ipaddr, dst_link->status.src_port, dst_link->status.dst_ipaddr, dst_link->status.dst_port); dst_link->status.stats.tx_ping_errors++; break; case 0: break; case 1: dst_link->status.stats.tx_ping_retries++; goto retry; break; } } else { dst_link->last_ping_size = outlen; } } timespec_diff(pong_last, clock_now, &diff_ping); if ((pong_last.tv_nsec) && (diff_ping >= (dst_link->pong_timeout * 1000llu))) { _link_down(knet_h, dst_host, dst_link); } } void _send_pings(knet_handle_t knet_h, int timed) { struct knet_host *dst_host; int link_idx; if (pthread_mutex_lock(&knet_h->hb_mutex)) { log_debug(knet_h, KNET_SUB_HEARTBEAT, "Unable to get hb mutex lock"); return; } for (dst_host = knet_h->host_head; dst_host != NULL; dst_host = dst_host->next) { for (link_idx = 0; link_idx < KNET_MAX_LINK; link_idx++) { if ((dst_host->link[link_idx].status.enabled != 1) || (dst_host->link[link_idx].transport_type == KNET_TRANSPORT_LOOPBACK ) || ((dst_host->link[link_idx].dynamic == KNET_LINK_DYNIP) && (dst_host->link[link_idx].status.dynconnected != 1))) continue; _handle_check_each(knet_h, dst_host, &dst_host->link[link_idx], timed); } } pthread_mutex_unlock(&knet_h->hb_mutex); } void *_handle_heartbt_thread(void *data) { knet_handle_t knet_h = (knet_handle_t) data; /* preparing ping buffer */ knet_h->pingbuf->kh_version = KNET_HEADER_VERSION; knet_h->pingbuf->kh_type = KNET_HEADER_TYPE_PING; knet_h->pingbuf->kh_node = htons(knet_h->host_id); while (!shutdown_in_progress(knet_h)) { usleep(KNET_THREADS_TIMERES); if (pthread_rwlock_rdlock(&knet_h->global_rwlock) != 0) { log_debug(knet_h, KNET_SUB_HEARTBEAT, "Unable to get read lock"); continue; } _send_pings(knet_h, 1); pthread_rwlock_unlock(&knet_h->global_rwlock); } return NULL; } diff --git a/libknet/threads_pmtud.c b/libknet/threads_pmtud.c index e239162a..c6caf4b2 100644 --- a/libknet/threads_pmtud.c +++ b/libknet/threads_pmtud.c @@ -1,409 +1,410 @@ /* * Copyright (C) 2015-2017 Red Hat, Inc. All rights reserved. * * Authors: Fabio M. Di Nitto * Federico Simoncelli * * This software licensed under GPL-2.0+, LGPL-2.0+ */ #include "config.h" #include #include #include #include #include "crypto.h" #include "links.h" #include "host.h" #include "logging.h" +#include "transports.h" #include "threads_common.h" #include "threads_pmtud.h" static int _handle_check_link_pmtud(knet_handle_t knet_h, struct knet_host *dst_host, struct knet_link *dst_link) { int err, ret, savederrno, mutex_retry_limit, failsafe; size_t onwire_len; /* current packet onwire size */ size_t overhead_len; /* onwire packet overhead (protocol based) */ size_t max_mtu_len; /* max mtu for protocol */ size_t data_len; /* how much data we can send in the packet * generally would be onwire_len - overhead_len * needs to be adjusted for crypto */ size_t pad_len; /* crypto packet pad size, needs to move into crypto.c callbacks */ ssize_t len; /* len of what we were able to sendto onwire */ struct timespec ts; unsigned char *outbuf = (unsigned char *)knet_h->pmtudbuf; mutex_retry_limit = 0; failsafe = 0; pad_len = 0; dst_link->last_bad_mtu = 0; knet_h->pmtudbuf->khp_pmtud_link = dst_link->link_id; switch (dst_link->dst_addr.ss_family) { case AF_INET6: max_mtu_len = KNET_PMTUD_SIZE_V6; overhead_len = KNET_PMTUD_OVERHEAD_V6 + dst_link->proto_overhead; dst_link->last_good_mtu = dst_link->last_ping_size + overhead_len; break; case AF_INET: max_mtu_len = KNET_PMTUD_SIZE_V4; overhead_len = KNET_PMTUD_OVERHEAD_V4 + dst_link->proto_overhead; dst_link->last_good_mtu = dst_link->last_ping_size + overhead_len; break; default: log_debug(knet_h, KNET_SUB_PMTUD, "PMTUD aborted, unknown protocol"); return -1; break; } /* * discovery starts from the top because kernel will * refuse to send packets > current iface mtu. * this saves us some time and network bw. */ onwire_len = max_mtu_len; restart: /* * prevent a race when interface mtu is changed _exactly_ during * the discovery process and it's complex to detect. Easier * to wait the next loop. * 30 is not an arbitrary value. To bisect from 576 to 128000 doesn't * take more than 18/19 steps. */ if (failsafe == 30) { log_err(knet_h, KNET_SUB_PMTUD, "Aborting PMTUD process: Too many attempts. MTU might have changed during discovery."); return -1; } else { failsafe++; } data_len = onwire_len - overhead_len; if (knet_h->crypto_instance) { if (knet_h->sec_block_size) { pad_len = knet_h->sec_block_size - (data_len % knet_h->sec_block_size); if (pad_len == knet_h->sec_block_size) { pad_len = 0; } data_len = data_len + pad_len; } data_len = data_len + (knet_h->sec_hash_size + knet_h->sec_salt_size + knet_h->sec_block_size); if (knet_h->sec_block_size) { while (data_len + overhead_len >= max_mtu_len) { data_len = data_len - knet_h->sec_block_size; } } if (dst_link->last_bad_mtu) { while (data_len + overhead_len >= dst_link->last_bad_mtu) { data_len = data_len - (knet_h->sec_hash_size + knet_h->sec_salt_size + knet_h->sec_block_size); } } if (data_len < (knet_h->sec_hash_size + knet_h->sec_salt_size + knet_h->sec_block_size) + 1) { log_debug(knet_h, KNET_SUB_PMTUD, "Aborting PMTUD process: link mtu smaller than crypto header detected (link might have been disconnected)"); return -1; } onwire_len = data_len + overhead_len; knet_h->pmtudbuf->khp_pmtud_size = onwire_len; if (crypto_encrypt_and_sign(knet_h, (const unsigned char *)knet_h->pmtudbuf, data_len - (knet_h->sec_hash_size + knet_h->sec_salt_size + knet_h->sec_block_size), knet_h->pmtudbuf_crypt, (ssize_t *)&data_len) < 0) { log_debug(knet_h, KNET_SUB_PMTUD, "Unable to crypto pmtud packet"); return -1; } outbuf = knet_h->pmtudbuf_crypt; } else { knet_h->pmtudbuf->khp_pmtud_size = onwire_len; } /* link has gone down, aborting pmtud */ if (dst_link->status.connected != 1) { log_debug(knet_h, KNET_SUB_PMTUD, "PMTUD detected host (%u) link (%u) has been disconnected", dst_host->host_id, dst_link->link_id); return -1; } if (dst_link->transport_connected != 1) { log_debug(knet_h, KNET_SUB_PMTUD, "PMTUD detected host (%u) link (%u) has been disconnected", dst_host->host_id, dst_link->link_id); return -1; } if (pthread_mutex_lock(&knet_h->pmtud_mutex) != 0) { log_debug(knet_h, KNET_SUB_PMTUD, "Unable to get mutex lock"); return -1; } retry: len = sendto(dst_link->outsock, outbuf, data_len, MSG_DONTWAIT | MSG_NOSIGNAL, (struct sockaddr *) &dst_link->dst_addr, sizeof(struct sockaddr_storage)); savederrno = errno; - err = knet_h->transport_ops[dst_link->transport_type]->transport_tx_sock_error(knet_h, dst_link->outsock, len, savederrno); + err = transport_tx_sock_error(knet_h, dst_link->transport_type, dst_link->outsock, len, savederrno); switch(err) { case -1: /* unrecoverable error */ log_debug(knet_h, KNET_SUB_PMTUD, "Unable to send pmtu packet (sendto): %d %s", savederrno, strerror(savederrno)); pthread_mutex_unlock(&knet_h->pmtud_mutex); dst_link->status.stats.tx_pmtu_errors++; return -1; case 0: /* ignore error and continue */ break; case 1: /* retry to send those same data */ dst_link->status.stats.tx_pmtu_retries++; goto retry; break; } if (len != (ssize_t )data_len) { if (savederrno == EMSGSIZE) { dst_link->last_bad_mtu = onwire_len; } else { log_debug(knet_h, KNET_SUB_PMTUD, "Unable to send pmtu packet len: %zu err: %s", onwire_len, strerror(savederrno)); } } else { dst_link->last_sent_mtu = onwire_len; dst_link->last_recv_mtu = 0; dst_link->status.stats.tx_pmtu_packets++; dst_link->status.stats.tx_pmtu_bytes += data_len; if (clock_gettime(CLOCK_REALTIME, &ts) < 0) { log_debug(knet_h, KNET_SUB_PMTUD, "Unable to get current time: %s", strerror(errno)); pthread_mutex_unlock(&knet_h->pmtud_mutex); return -1; } /* * Set an artibrary 2 seconds timeout to receive a PMTUd reply * perhaps this should be configurable but: * 1) too short timeout can cause instability since MTU value * influeces link status * 2) too high timeout slows down the MTU detection process for * small MTU * * Another option is to make the PMTUd process less influent * in link status detection but that could cause data packet loss * without link up/down changes */ ts.tv_sec += 2; ret = pthread_cond_timedwait(&knet_h->pmtud_cond, &knet_h->pmtud_mutex, &ts); if (shutdown_in_progress(knet_h)) { pthread_mutex_unlock(&knet_h->pmtud_mutex); log_debug(knet_h, KNET_SUB_PMTUD, "PMTUD aborted. shutdown in progress"); return -1; } if ((ret != 0) && (ret != ETIMEDOUT)) { pthread_mutex_unlock(&knet_h->pmtud_mutex); if (mutex_retry_limit == 3) { log_debug(knet_h, KNET_SUB_PMTUD, "PMTUD aborted, unable to get mutex lock"); return -1; } mutex_retry_limit++; goto restart; } if ((dst_link->last_recv_mtu != onwire_len) || (ret)) { dst_link->last_bad_mtu = onwire_len; } else { int found_mtu = 0; if (knet_h->sec_block_size) { if ((onwire_len + knet_h->sec_block_size >= max_mtu_len) || ((dst_link->last_bad_mtu) && (dst_link->last_bad_mtu <= (onwire_len + knet_h->sec_block_size)))) { found_mtu = 1; } } else { if ((onwire_len == max_mtu_len) || ((dst_link->last_bad_mtu) && (dst_link->last_bad_mtu == (onwire_len + 1)))) { found_mtu = 1; } } if (found_mtu) { /* * account for IP overhead, knet headers and crypto in PMTU calculation */ dst_link->status.mtu = onwire_len - dst_link->status.proto_overhead; pthread_mutex_unlock(&knet_h->pmtud_mutex); return 0; } dst_link->last_good_mtu = onwire_len; } } onwire_len = (dst_link->last_good_mtu + dst_link->last_bad_mtu) / 2; pthread_mutex_unlock(&knet_h->pmtud_mutex); goto restart; } static int _handle_check_pmtud(knet_handle_t knet_h, struct knet_host *dst_host, struct knet_link *dst_link, unsigned int *min_mtu) { uint8_t saved_valid_pmtud; unsigned int saved_pmtud; struct timespec clock_now; unsigned long long diff_pmtud, interval; interval = knet_h->pmtud_interval * 1000000000llu; /* nanoseconds */ if (clock_gettime(CLOCK_MONOTONIC, &clock_now) != 0) { log_debug(knet_h, KNET_SUB_PMTUD, "Unable to get monotonic clock"); return 0; } timespec_diff(dst_link->pmtud_last, clock_now, &diff_pmtud); if (diff_pmtud < interval) { *min_mtu = dst_link->status.mtu; return dst_link->has_valid_mtu; } switch (dst_link->dst_addr.ss_family) { case AF_INET6: dst_link->status.proto_overhead = KNET_PMTUD_OVERHEAD_V6 + dst_link->proto_overhead + KNET_HEADER_ALL_SIZE + knet_h->sec_header_size; break; case AF_INET: dst_link->status.proto_overhead = KNET_PMTUD_OVERHEAD_V4 + dst_link->proto_overhead + KNET_HEADER_ALL_SIZE + knet_h->sec_header_size; break; } saved_pmtud = dst_link->status.mtu; saved_valid_pmtud = dst_link->has_valid_mtu; log_debug(knet_h, KNET_SUB_PMTUD, "Starting PMTUD for host: %u link: %u", dst_host->host_id, dst_link->link_id); if (_handle_check_link_pmtud(knet_h, dst_host, dst_link) < 0) { dst_link->has_valid_mtu = 0; } else { dst_link->has_valid_mtu = 1; switch (dst_link->dst_addr.ss_family) { case AF_INET6: if (((dst_link->status.mtu + dst_link->status.proto_overhead) < KNET_PMTUD_MIN_MTU_V6) || ((dst_link->status.mtu + dst_link->status.proto_overhead) > KNET_PMTUD_SIZE_V6)) { log_debug(knet_h, KNET_SUB_PMTUD, "PMTUD detected an IPv6 MTU out of bound value (%u) for host: %u link: %u.", dst_link->status.mtu + dst_link->status.proto_overhead, dst_host->host_id, dst_link->link_id); dst_link->has_valid_mtu = 0; } break; case AF_INET: if (((dst_link->status.mtu + dst_link->status.proto_overhead) < KNET_PMTUD_MIN_MTU_V4) || ((dst_link->status.mtu + dst_link->status.proto_overhead) > KNET_PMTUD_SIZE_V4)) { log_debug(knet_h, KNET_SUB_PMTUD, "PMTUD detected an IPv4 MTU out of bound value (%u) for host: %u link: %u.", dst_link->status.mtu + dst_link->status.proto_overhead, dst_host->host_id, dst_link->link_id); dst_link->has_valid_mtu = 0; } break; } if (dst_link->has_valid_mtu) { if ((saved_pmtud) && (saved_pmtud != dst_link->status.mtu)) { log_info(knet_h, KNET_SUB_PMTUD, "PMTUD link change for host: %u link: %u from %u to %u", dst_host->host_id, dst_link->link_id, saved_pmtud, dst_link->status.mtu); } log_debug(knet_h, KNET_SUB_PMTUD, "PMTUD completed for host: %u link: %u current link mtu: %u", dst_host->host_id, dst_link->link_id, dst_link->status.mtu); if (dst_link->status.mtu < *min_mtu) { *min_mtu = dst_link->status.mtu; } dst_link->pmtud_last = clock_now; } } if (saved_valid_pmtud != dst_link->has_valid_mtu) { _host_dstcache_update_sync(knet_h, dst_host); } return dst_link->has_valid_mtu; } void *_handle_pmtud_link_thread(void *data) { knet_handle_t knet_h = (knet_handle_t) data; struct knet_host *dst_host; struct knet_link *dst_link; int link_idx; unsigned int min_mtu, have_mtu; unsigned int lower_mtu; knet_h->data_mtu = KNET_PMTUD_MIN_MTU_V4 - KNET_HEADER_ALL_SIZE - knet_h->sec_header_size; /* preparing pmtu buffer */ knet_h->pmtudbuf->kh_version = KNET_HEADER_VERSION; knet_h->pmtudbuf->kh_type = KNET_HEADER_TYPE_PMTUD; knet_h->pmtudbuf->kh_node = htons(knet_h->host_id); while (!shutdown_in_progress(knet_h)) { usleep(KNET_THREADS_TIMERES); if (pthread_rwlock_rdlock(&knet_h->global_rwlock) != 0) { log_debug(knet_h, KNET_SUB_PMTUD, "Unable to get read lock"); continue; } lower_mtu = KNET_PMTUD_SIZE_V4; min_mtu = KNET_PMTUD_SIZE_V4 - KNET_HEADER_ALL_SIZE - knet_h->sec_header_size; have_mtu = 0; for (dst_host = knet_h->host_head; dst_host != NULL; dst_host = dst_host->next) { for (link_idx = 0; link_idx < KNET_MAX_LINK; link_idx++) { dst_link = &dst_host->link[link_idx]; if ((dst_link->status.enabled != 1) || (dst_link->status.connected != 1) || (dst_host->link[link_idx].transport_type == KNET_TRANSPORT_LOOPBACK) || (!dst_link->last_ping_size) || ((dst_link->dynamic == KNET_LINK_DYNIP) && (dst_link->status.dynconnected != 1))) continue; if (_handle_check_pmtud(knet_h, dst_host, dst_link, &min_mtu)) { have_mtu = 1; if (min_mtu < lower_mtu) { lower_mtu = min_mtu; } } } } if (have_mtu) { if (knet_h->data_mtu != lower_mtu) { knet_h->data_mtu = lower_mtu; log_info(knet_h, KNET_SUB_PMTUD, "Global data MTU changed to: %u", knet_h->data_mtu); if (knet_h->pmtud_notify_fn) { knet_h->pmtud_notify_fn(knet_h->pmtud_notify_fn_private_data, knet_h->data_mtu); } } } pthread_rwlock_unlock(&knet_h->global_rwlock); } return NULL; } diff --git a/libknet/threads_rx.c b/libknet/threads_rx.c index 12d6a171..95b23c39 100644 --- a/libknet/threads_rx.c +++ b/libknet/threads_rx.c @@ -1,820 +1,821 @@ /* * Copyright (C) 2012-2017 Red Hat, Inc. All rights reserved. * * Authors: Fabio M. Di Nitto * Federico Simoncelli * * This software licensed under GPL-2.0+, LGPL-2.0+ */ #include "config.h" #include #include #include #include #include #include "compat.h" #include "compress.h" #include "crypto.h" #include "host.h" #include "links.h" #include "logging.h" #include "transports.h" +#include "transport_common.h" #include "threads_common.h" #include "threads_heartbeat.h" #include "threads_rx.h" #include "netutils.h" /* * RECV */ /* * return 1 if a > b * return -1 if b > a * return 0 if they are equal */ static inline int timecmp(struct timespec a, struct timespec b) { if (a.tv_sec != b.tv_sec) { if (a.tv_sec > b.tv_sec) { return 1; } else { return -1; } } else { if (a.tv_nsec > b.tv_nsec) { return 1; } else if (a.tv_nsec < b.tv_nsec) { return -1; } else { return 0; } } } /* * this functions needs to return an index (0 to 7) * to a knet_host_defrag_buf. (-1 on errors) */ static int find_pckt_defrag_buf(knet_handle_t knet_h, struct knet_header *inbuf) { struct knet_host *src_host = knet_h->host_index[inbuf->kh_node]; int i, oldest; /* * check if there is a buffer already in use handling the same seq_num */ for (i = 0; i < KNET_MAX_LINK; i++) { if (src_host->defrag_buf[i].in_use) { if (src_host->defrag_buf[i].pckt_seq == inbuf->khp_data_seq_num) { return i; } } } /* * If there is no buffer that's handling the current seq_num * either it's new or it's been reclaimed already. * check if it's been reclaimed/seen before using the defrag circular * buffer. If the pckt has been seen before, the buffer expired (ETIME) * and there is no point to try to defrag it again. */ if (!_seq_num_lookup(src_host, inbuf->khp_data_seq_num, 1, 0)) { errno = ETIME; return -1; } /* * register the pckt as seen */ _seq_num_set(src_host, inbuf->khp_data_seq_num, 1); /* * see if there is a free buffer */ for (i = 0; i < KNET_MAX_LINK; i++) { if (!src_host->defrag_buf[i].in_use) { return i; } } /* * at this point, there are no free buffers, the pckt is new * and we need to reclaim a buffer, and we will take the one * with the oldest timestamp. It's as good as any. */ oldest = 0; for (i = 0; i < KNET_MAX_LINK; i++) { if (timecmp(src_host->defrag_buf[i].last_update, src_host->defrag_buf[oldest].last_update) < 0) { oldest = i; } } src_host->defrag_buf[oldest].in_use = 0; return oldest; } static int pckt_defrag(knet_handle_t knet_h, struct knet_header *inbuf, ssize_t *len) { struct knet_host_defrag_buf *defrag_buf; int defrag_buf_idx; defrag_buf_idx = find_pckt_defrag_buf(knet_h, inbuf); if (defrag_buf_idx < 0) { if (errno == ETIME) { log_debug(knet_h, KNET_SUB_RX, "Defrag buffer expired"); } return 1; } defrag_buf = &knet_h->host_index[inbuf->kh_node]->defrag_buf[defrag_buf_idx]; /* * if the buf is not is use, then make sure it's clean */ if (!defrag_buf->in_use) { memset(defrag_buf, 0, sizeof(struct knet_host_defrag_buf)); defrag_buf->in_use = 1; defrag_buf->pckt_seq = inbuf->khp_data_seq_num; } /* * update timestamp on the buffer */ clock_gettime(CLOCK_MONOTONIC, &defrag_buf->last_update); /* * check if we already received this fragment */ if (defrag_buf->frag_map[inbuf->khp_data_frag_seq]) { /* * if we have received this fragment and we didn't clear the buffer * it means that we don't have all fragments yet */ return 1; } /* * we need to handle the last packet with gloves due to its different size */ if (inbuf->khp_data_frag_seq == inbuf->khp_data_frag_num) { defrag_buf->last_frag_size = *len; /* * in the event when the last packet arrives first, * we still don't know the offset vs the other fragments (based on MTU), * so we store the fragment at the end of the buffer where it's safe * and take a copy of the len so that we can restore its offset later. * remember we can't use the local MTU for this calculation because pMTU * can be asymettric between the same hosts. */ if (!defrag_buf->frag_size) { defrag_buf->last_first = 1; memmove(defrag_buf->buf + (KNET_MAX_PACKET_SIZE - *len), inbuf->khp_data_userdata, *len); } } else { defrag_buf->frag_size = *len; } memmove(defrag_buf->buf + ((inbuf->khp_data_frag_seq - 1) * defrag_buf->frag_size), inbuf->khp_data_userdata, *len); defrag_buf->frag_recv++; defrag_buf->frag_map[inbuf->khp_data_frag_seq] = 1; /* * check if we received all the fragments */ if (defrag_buf->frag_recv == inbuf->khp_data_frag_num) { /* * special case the last pckt */ if (defrag_buf->last_first) { memmove(defrag_buf->buf + ((inbuf->khp_data_frag_num - 1) * defrag_buf->frag_size), defrag_buf->buf + (KNET_MAX_PACKET_SIZE - defrag_buf->last_frag_size), defrag_buf->last_frag_size); } /* * recalculate packet lenght */ *len = ((inbuf->khp_data_frag_num - 1) * defrag_buf->frag_size) + defrag_buf->last_frag_size; /* * copy the pckt back in the user data */ memmove(inbuf->khp_data_userdata, defrag_buf->buf, *len); /* * free this buffer */ defrag_buf->in_use = 0; return 0; } return 1; } static void _parse_recv_from_links(knet_handle_t knet_h, int sockfd, const struct knet_mmsghdr *msg) { int err = 0, savederrno = 0; ssize_t outlen; struct knet_host *src_host; struct knet_link *src_link; unsigned long long latency_last; knet_node_id_t dst_host_ids[KNET_MAX_HOST]; size_t dst_host_ids_entries = 0; int bcast = 1; struct timespec recvtime; struct knet_header *inbuf = msg->msg_hdr.msg_iov->iov_base; unsigned char *outbuf = (unsigned char *)msg->msg_hdr.msg_iov->iov_base; ssize_t len = msg->msg_len; struct knet_hostinfo *knet_hostinfo; struct iovec iov_out[1]; int8_t channel; struct sockaddr_storage pckt_src; seq_num_t recv_seq_num; int wipe_bufs = 0; if (knet_h->crypto_instance) { struct timespec start_time; struct timespec end_time; uint64_t crypt_time; clock_gettime(CLOCK_MONOTONIC, &start_time); if (crypto_authenticate_and_decrypt(knet_h, (unsigned char *)inbuf, len, knet_h->recv_from_links_buf_decrypt, &outlen) < 0) { log_debug(knet_h, KNET_SUB_RX, "Unable to decrypt/auth packet"); return; } clock_gettime(CLOCK_MONOTONIC, &end_time); timespec_diff(start_time, end_time, &crypt_time); if (crypt_time < knet_h->stats.rx_crypt_time_min) { knet_h->stats.rx_crypt_time_min = crypt_time; } if (crypt_time > knet_h->stats.rx_crypt_time_max) { knet_h->stats.rx_crypt_time_max = crypt_time; } knet_h->stats.rx_crypt_time_ave = (knet_h->stats.rx_crypt_time_ave * knet_h->stats.rx_crypt_packets + crypt_time) / (knet_h->stats.rx_crypt_packets+1); knet_h->stats.rx_crypt_packets++; len = outlen; inbuf = (struct knet_header *)knet_h->recv_from_links_buf_decrypt; } if (len < (ssize_t)(KNET_HEADER_SIZE + 1)) { log_debug(knet_h, KNET_SUB_RX, "Packet is too short: %ld", (long)len); return; } if (inbuf->kh_version != KNET_HEADER_VERSION) { log_debug(knet_h, KNET_SUB_RX, "Packet version does not match"); return; } inbuf->kh_node = ntohs(inbuf->kh_node); src_host = knet_h->host_index[inbuf->kh_node]; if (src_host == NULL) { /* host not found */ log_debug(knet_h, KNET_SUB_RX, "Unable to find source host for this packet"); return; } src_link = NULL; src_link = src_host->link + (inbuf->khp_ping_link % KNET_MAX_LINK); if ((inbuf->kh_type & KNET_HEADER_TYPE_PMSK) != 0) { if (src_link->dynamic == KNET_LINK_DYNIP) { /* * cpyaddrport will only copy address and port of the incoming * packet and strip extra bits such as flow and scopeid */ cpyaddrport(&pckt_src, msg->msg_hdr.msg_name); if (cmpaddr(&src_link->dst_addr, sockaddr_len(&src_link->dst_addr), &pckt_src, sockaddr_len(&pckt_src)) != 0) { log_debug(knet_h, KNET_SUB_RX, "host: %u link: %u appears to have changed ip address", src_host->host_id, src_link->link_id); memmove(&src_link->dst_addr, &pckt_src, sizeof(struct sockaddr_storage)); if (knet_addrtostr(&src_link->dst_addr, sockaddr_len(msg->msg_hdr.msg_name), src_link->status.dst_ipaddr, KNET_MAX_HOST_LEN, src_link->status.dst_port, KNET_MAX_PORT_LEN) != 0) { log_debug(knet_h, KNET_SUB_RX, "Unable to resolve ???"); snprintf(src_link->status.dst_ipaddr, KNET_MAX_HOST_LEN - 1, "Unknown!!!"); snprintf(src_link->status.dst_port, KNET_MAX_PORT_LEN - 1, "??"); } else { log_info(knet_h, KNET_SUB_RX, "host: %u link: %u new connection established from: %s %s", src_host->host_id, src_link->link_id, src_link->status.dst_ipaddr, src_link->status.dst_port); } } /* * transport has already accepted the connection here * otherwise we would not be receiving packets */ - knet_h->transport_ops[src_link->transport_type]->transport_link_dyn_connect(knet_h, sockfd, src_link); + transport_link_dyn_connect(knet_h, sockfd, src_link); } } switch (inbuf->kh_type) { case KNET_HEADER_TYPE_HOST_INFO: case KNET_HEADER_TYPE_DATA: /* * TODO: should we accept data even if we can't reply to the other node? * how would that work with SCTP and guaranteed delivery? */ if (!src_host->status.reachable) { log_debug(knet_h, KNET_SUB_RX, "Source host %u not reachable yet", src_host->host_id); //return; } inbuf->khp_data_seq_num = ntohs(inbuf->khp_data_seq_num); channel = inbuf->khp_data_channel; src_host->got_data = 1; if (src_link) { src_link->status.stats.rx_data_packets++; src_link->status.stats.rx_data_bytes += len; } if (!_seq_num_lookup(src_host, inbuf->khp_data_seq_num, 0, 0)) { if (src_host->link_handler_policy != KNET_LINK_POLICY_ACTIVE) { log_debug(knet_h, KNET_SUB_RX, "Packet has already been delivered"); } return; } if (inbuf->khp_data_frag_num > 1) { /* * len as received from the socket also includes extra stuff * that the defrag code doesn't care about. So strip it * here and readd only for repadding once we are done * defragging */ len = len - KNET_HEADER_DATA_SIZE; if (pckt_defrag(knet_h, inbuf, &len)) { return; } len = len + KNET_HEADER_DATA_SIZE; } if (inbuf->khp_data_compress) { ssize_t decmp_outlen = KNET_DATABUFSIZE_COMPRESS; struct timespec start_time; struct timespec end_time; uint64_t compress_time; clock_gettime(CLOCK_MONOTONIC, &start_time); err = decompress(knet_h, inbuf->khp_data_compress, (const unsigned char *)inbuf->khp_data_userdata, len - KNET_HEADER_DATA_SIZE, knet_h->recv_from_links_buf_decompress, &decmp_outlen); if (!err) { /* Collect stats */ clock_gettime(CLOCK_MONOTONIC, &end_time); timespec_diff(start_time, end_time, &compress_time); if (compress_time < knet_h->stats.rx_compress_time_min) { knet_h->stats.rx_compress_time_min = compress_time; } if (compress_time > knet_h->stats.rx_compress_time_max) { knet_h->stats.rx_compress_time_max = compress_time; } knet_h->stats.rx_compress_time_ave = (knet_h->stats.rx_compress_time_ave * knet_h->stats.rx_compressed_packets + compress_time) / (knet_h->stats.rx_compressed_packets+1); knet_h->stats.rx_compressed_packets++; knet_h->stats.rx_compressed_original_bytes += decmp_outlen; knet_h->stats.rx_compressed_size_bytes += len - KNET_HEADER_SIZE; memmove(inbuf->khp_data_userdata, knet_h->recv_from_links_buf_decompress, decmp_outlen); len = decmp_outlen + KNET_HEADER_DATA_SIZE; } else { log_warn(knet_h, KNET_SUB_COMPRESS, "Unable to decompress packet (%d): %s", err, strerror(errno)); return; } } if (inbuf->kh_type == KNET_HEADER_TYPE_DATA) { if (knet_h->enabled != 1) /* data forward is disabled */ break; if (knet_h->dst_host_filter_fn) { size_t host_idx; int found = 0; bcast = knet_h->dst_host_filter_fn( knet_h->dst_host_filter_fn_private_data, (const unsigned char *)inbuf->khp_data_userdata, len - KNET_HEADER_DATA_SIZE, KNET_NOTIFY_RX, knet_h->host_id, inbuf->kh_node, &channel, dst_host_ids, &dst_host_ids_entries); if (bcast < 0) { log_debug(knet_h, KNET_SUB_RX, "Error from dst_host_filter_fn: %d", bcast); return; } if ((!bcast) && (!dst_host_ids_entries)) { log_debug(knet_h, KNET_SUB_RX, "Message is unicast but no dst_host_ids_entries"); return; } /* check if we are dst for this packet */ if (!bcast) { for (host_idx = 0; host_idx < dst_host_ids_entries; host_idx++) { if (dst_host_ids[host_idx] == knet_h->host_id) { found = 1; break; } } if (!found) { log_debug(knet_h, KNET_SUB_RX, "Packet is not for us"); return; } } } } if (inbuf->kh_type == KNET_HEADER_TYPE_DATA) { if (!knet_h->sockfd[channel].in_use) { log_debug(knet_h, KNET_SUB_RX, "received packet for channel %d but there is no local sock connected", channel); return; } memset(iov_out, 0, sizeof(iov_out)); iov_out[0].iov_base = (void *) inbuf->khp_data_userdata; iov_out[0].iov_len = len - KNET_HEADER_DATA_SIZE; outlen = writev(knet_h->sockfd[channel].sockfd[knet_h->sockfd[channel].is_created], iov_out, 1); if (outlen <= 0) { knet_h->sock_notify_fn(knet_h->sock_notify_fn_private_data, knet_h->sockfd[channel].sockfd[0], channel, KNET_NOTIFY_RX, outlen, errno); return; } if ((size_t)outlen == iov_out[0].iov_len) { _seq_num_set(src_host, inbuf->khp_data_seq_num, 0); } } else { /* HOSTINFO */ knet_hostinfo = (struct knet_hostinfo *)inbuf->khp_data_userdata; if (knet_hostinfo->khi_bcast == KNET_HOSTINFO_UCAST) { bcast = 0; knet_hostinfo->khi_dst_node_id = ntohs(knet_hostinfo->khi_dst_node_id); } if (!_seq_num_lookup(src_host, inbuf->khp_data_seq_num, 0, 0)) { return; } _seq_num_set(src_host, inbuf->khp_data_seq_num, 0); switch(knet_hostinfo->khi_type) { case KNET_HOSTINFO_TYPE_LINK_UP_DOWN: break; case KNET_HOSTINFO_TYPE_LINK_TABLE: break; default: log_warn(knet_h, KNET_SUB_RX, "Receiving unknown host info message from host %u", src_host->host_id); break; } } break; case KNET_HEADER_TYPE_PING: outlen = KNET_HEADER_PING_SIZE; inbuf->kh_type = KNET_HEADER_TYPE_PONG; inbuf->kh_node = htons(knet_h->host_id); recv_seq_num = ntohs(inbuf->khp_ping_seq_num); src_link->status.stats.rx_ping_packets++; src_link->status.stats.rx_ping_bytes += len; wipe_bufs = 0; if (!inbuf->khp_ping_timed) { /* * we might be receiving this message from all links, but we want * to process it only the first time */ if (recv_seq_num != src_host->untimed_rx_seq_num) { /* * cache the untimed seq num */ src_host->untimed_rx_seq_num = recv_seq_num; /* * if the host has received data in between * untimed ping, then we don't need to wipe the bufs */ if (src_host->got_data) { src_host->got_data = 0; wipe_bufs = 0; } else { wipe_bufs = 1; } } _seq_num_lookup(src_host, recv_seq_num, 0, wipe_bufs); } else { /* * pings always arrives in bursts over all the link * catch the first of them to cache the seq num and * avoid duplicate processing */ if (recv_seq_num != src_host->timed_rx_seq_num) { src_host->timed_rx_seq_num = recv_seq_num; if (recv_seq_num == 0) { _seq_num_lookup(src_host, recv_seq_num, 0, 1); } } } if (knet_h->crypto_instance) { if (crypto_encrypt_and_sign(knet_h, (const unsigned char *)inbuf, len, knet_h->recv_from_links_buf_crypt, &outlen) < 0) { log_debug(knet_h, KNET_SUB_RX, "Unable to encrypt pong packet"); break; } outbuf = knet_h->recv_from_links_buf_crypt; } retry_pong: len = sendto(src_link->outsock, outbuf, outlen, MSG_DONTWAIT | MSG_NOSIGNAL, (struct sockaddr *) &src_link->dst_addr, sizeof(struct sockaddr_storage)); savederrno = errno; if (len != outlen) { - err = knet_h->transport_ops[src_link->transport_type]->transport_tx_sock_error(knet_h, src_link->outsock, len, savederrno); + err = transport_tx_sock_error(knet_h, src_link->transport_type, src_link->outsock, len, savederrno); switch(err) { case -1: /* unrecoverable error */ log_debug(knet_h, KNET_SUB_RX, "Unable to send pong reply (sock: %d) packet (sendto): %d %s. recorded src ip: %s src port: %s dst ip: %s dst port: %s", src_link->outsock, errno, strerror(errno), src_link->status.src_ipaddr, src_link->status.src_port, src_link->status.dst_ipaddr, src_link->status.dst_port); src_link->status.stats.tx_pong_errors++; break; case 0: /* ignore error and continue */ break; case 1: /* retry to send those same data */ src_link->status.stats.tx_pong_retries++; goto retry_pong; break; } } src_link->status.stats.tx_pong_packets++; src_link->status.stats.tx_pong_bytes += outlen; break; case KNET_HEADER_TYPE_PONG: src_link->status.stats.rx_pong_packets++; src_link->status.stats.rx_pong_bytes += len; clock_gettime(CLOCK_MONOTONIC, &src_link->status.pong_last); memmove(&recvtime, &inbuf->khp_ping_time[0], sizeof(struct timespec)); timespec_diff(recvtime, src_link->status.pong_last, &latency_last); src_link->status.latency = ((src_link->status.latency * src_link->latency_exp) + ((latency_last / 1000llu) * (src_link->latency_fix - src_link->latency_exp))) / src_link->latency_fix; if (src_link->status.latency < src_link->pong_timeout) { if (!src_link->status.connected) { if (src_link->received_pong >= src_link->pong_count) { log_info(knet_h, KNET_SUB_RX, "host: %u link: %u is up", src_host->host_id, src_link->link_id); _link_updown(knet_h, src_host->host_id, src_link->link_id, src_link->status.enabled, 1); } else { src_link->received_pong++; log_debug(knet_h, KNET_SUB_RX, "host: %u link: %u received pong: %u", src_host->host_id, src_link->link_id, src_link->received_pong); } } } /* Calculate latency stats */ if (src_link->status.latency > src_link->status.stats.latency_max) { src_link->status.stats.latency_max = src_link->status.latency; } if (src_link->status.latency < src_link->status.stats.latency_min) { src_link->status.stats.latency_min = src_link->status.latency; } src_link->status.stats.latency_ave = (src_link->status.stats.latency_ave * src_link->status.stats.latency_samples + src_link->status.latency) / (src_link->status.stats.latency_samples+1); src_link->status.stats.latency_samples++; break; case KNET_HEADER_TYPE_PMTUD: src_link->status.stats.rx_pmtu_packets++; src_link->status.stats.rx_pmtu_bytes += len; outlen = KNET_HEADER_PMTUD_SIZE; inbuf->kh_type = KNET_HEADER_TYPE_PMTUD_REPLY; inbuf->kh_node = htons(knet_h->host_id); if (knet_h->crypto_instance) { if (crypto_encrypt_and_sign(knet_h, (const unsigned char *)inbuf, len, knet_h->recv_from_links_buf_crypt, &outlen) < 0) { log_debug(knet_h, KNET_SUB_RX, "Unable to encrypt PMTUd reply packet"); break; } outbuf = knet_h->recv_from_links_buf_crypt; } retry_pmtud: len = sendto(src_link->outsock, outbuf, outlen, MSG_DONTWAIT | MSG_NOSIGNAL, (struct sockaddr *) &src_link->dst_addr, sizeof(struct sockaddr_storage)); if (len != outlen) { - err = knet_h->transport_ops[src_link->transport_type]->transport_tx_sock_error(knet_h, src_link->outsock, len, savederrno); + err = transport_tx_sock_error(knet_h, src_link->transport_type, src_link->outsock, len, savederrno); switch(err) { case -1: /* unrecoverable error */ log_debug(knet_h, KNET_SUB_RX, "Unable to send PMTUd reply (sock: %d) packet (sendto): %d %s. recorded src ip: %s src port: %s dst ip: %s dst port: %s", src_link->outsock, errno, strerror(errno), src_link->status.src_ipaddr, src_link->status.src_port, src_link->status.dst_ipaddr, src_link->status.dst_port); src_link->status.stats.tx_pmtu_errors++; break; case 0: /* ignore error and continue */ src_link->status.stats.tx_pmtu_errors++; break; case 1: /* retry to send those same data */ src_link->status.stats.tx_pmtu_retries++; goto retry_pmtud; break; } } break; case KNET_HEADER_TYPE_PMTUD_REPLY: src_link->status.stats.rx_pmtu_packets++; src_link->status.stats.rx_pmtu_bytes += len; if (pthread_mutex_lock(&knet_h->pmtud_mutex) != 0) { log_debug(knet_h, KNET_SUB_RX, "Unable to get mutex lock"); break; } src_link->last_recv_mtu = inbuf->khp_pmtud_size; pthread_cond_signal(&knet_h->pmtud_cond); pthread_mutex_unlock(&knet_h->pmtud_mutex); break; default: return; } } static void _handle_recv_from_links(knet_handle_t knet_h, int sockfd, struct knet_mmsghdr *msg) { int err, savederrno; int i, msg_recv, transport; if (pthread_rwlock_rdlock(&knet_h->global_rwlock) != 0) { log_debug(knet_h, KNET_SUB_RX, "Unable to get global read lock"); return; } if (_is_valid_fd(knet_h, sockfd) < 1) { /* * this is normal if a fd got an event and before we grab the read lock * and the link is removed by another thread */ goto exit_unlock; } transport = knet_h->knet_transport_fd_tracker[sockfd].transport; /* * reset msg_namelen to buffer size because after recvmmsg * each msg_namelen will contain sizeof sockaddr_in or sockaddr_in6 */ for (i = 0; i < PCKT_RX_BUFS; i++) { msg[i].msg_hdr.msg_namelen = sizeof(struct sockaddr_storage); } msg_recv = _recvmmsg(sockfd, &msg[0], PCKT_RX_BUFS, MSG_DONTWAIT | MSG_NOSIGNAL); savederrno = errno; /* * WARNING: man page for recvmmsg is wrong. Kernel implementation here: * recvmmsg can return: * -1 on error * 0 if the previous run of recvmmsg recorded an error on the socket * N number of messages (see exception below). * * If there is an error from recvmsg after receiving a frame or more, the recvmmsg * loop is interrupted, error recorded in the socket (getsockopt(SO_ERROR) and * it will be visibile in the next run. * * Need to be careful how we handle errors at this stage. * * error messages need to be handled on a per transport/protocol base * at this point we have different layers of error handling * - msg_recv < 0 -> error from this run * msg_recv = 0 -> error from previous run and error on socket needs to be cleared * - per-transport message data * example: msg[i].msg_hdr.msg_flags & MSG_NOTIFICATION or msg_len for SCTP == EOF, * but for UDP it is perfectly legal to receive a 0 bytes message.. go figure * - NOTE: on SCTP MSG_NOTIFICATION we get msg_recv == PCKT_FRAG_MAX messages and no * errno set. That means the error api needs to be able to abort the loop below. */ if (msg_recv <= 0) { - knet_h->transport_ops[transport]->transport_rx_sock_error(knet_h, sockfd, msg_recv, savederrno); + transport_rx_sock_error(knet_h, transport, sockfd, msg_recv, savederrno); goto exit_unlock; } for (i = 0; i < msg_recv; i++) { - err = knet_h->transport_ops[transport]->transport_rx_is_data(knet_h, sockfd, &msg[i]); + err = transport_rx_is_data(knet_h, transport, sockfd, &msg[i]); /* * TODO: make this section silent once we are confident * all protocols packet handlers are good */ switch(err) { case -1: /* on error */ log_debug(knet_h, KNET_SUB_RX, "Transport reported error parsing packet"); goto exit_unlock; break; case 0: /* packet is not data and we should continue the packet process loop */ log_debug(knet_h, KNET_SUB_RX, "Transport reported no data, continue"); break; case 1: /* packet is not data and we should STOP the packet process loop */ log_debug(knet_h, KNET_SUB_RX, "Transport reported no data, stop"); goto exit_unlock; break; case 2: /* packet is data and should be parsed as such */ _parse_recv_from_links(knet_h, sockfd, &msg[i]); break; } } exit_unlock: pthread_rwlock_unlock(&knet_h->global_rwlock); } void *_handle_recv_from_links_thread(void *data) { int i, nev; knet_handle_t knet_h = (knet_handle_t) data; struct epoll_event events[KNET_EPOLL_MAX_EVENTS]; struct sockaddr_storage address[PCKT_RX_BUFS]; struct knet_mmsghdr msg[PCKT_RX_BUFS]; struct iovec iov_in[PCKT_RX_BUFS]; memset(&msg, 0, sizeof(msg)); for (i = 0; i < PCKT_RX_BUFS; i++) { iov_in[i].iov_base = (void *)knet_h->recv_from_links_buf[i]; iov_in[i].iov_len = KNET_DATABUFSIZE; memset(&msg[i].msg_hdr, 0, sizeof(struct msghdr)); msg[i].msg_hdr.msg_name = &address[i]; msg[i].msg_hdr.msg_namelen = sizeof(struct sockaddr_storage); msg[i].msg_hdr.msg_iov = &iov_in[i]; msg[i].msg_hdr.msg_iovlen = 1; } while (!shutdown_in_progress(knet_h)) { nev = epoll_wait(knet_h->recv_from_links_epollfd, events, KNET_EPOLL_MAX_EVENTS, -1); for (i = 0; i < nev; i++) { _handle_recv_from_links(knet_h, events[i].data.fd, msg); } } return NULL; } diff --git a/libknet/threads_tx.c b/libknet/threads_tx.c index 969f6c03..d065502d 100644 --- a/libknet/threads_tx.c +++ b/libknet/threads_tx.c @@ -1,736 +1,737 @@ /* * Copyright (C) 2012-2017 Red Hat, Inc. All rights reserved. * * Authors: Fabio M. Di Nitto * Federico Simoncelli * * This software licensed under GPL-2.0+, LGPL-2.0+ */ #include "config.h" #include #include #include #include #include #include #include "compat.h" #include "compress.h" #include "crypto.h" #include "host.h" #include "link.h" #include "logging.h" #include "transports.h" +#include "transport_common.h" #include "threads_common.h" #include "threads_heartbeat.h" #include "threads_tx.h" #include "netutils.h" /* * SEND */ static int _dispatch_to_links(knet_handle_t knet_h, struct knet_host *dst_host, struct knet_mmsghdr *msg, int msgs_to_send) { int link_idx, msg_idx, sent_msgs, prev_sent, progress; int err = 0, savederrno = 0; unsigned int i; struct knet_mmsghdr *cur; struct knet_link *cur_link; for (link_idx = 0; link_idx < dst_host->active_link_entries; link_idx++) { sent_msgs = 0; prev_sent = 0; progress = 1; cur_link = &dst_host->link[dst_host->active_links[link_idx]]; if (cur_link->transport_type == KNET_TRANSPORT_LOOPBACK) { continue; } msg_idx = 0; while (msg_idx < msgs_to_send) { msg[msg_idx].msg_hdr.msg_name = &cur_link->dst_addr; /* Cast for Linux/BSD compatibility */ for (i=0; i<(unsigned int)msg[msg_idx].msg_hdr.msg_iovlen; i++) { cur_link->status.stats.tx_data_bytes += msg[msg_idx].msg_hdr.msg_iov[i].iov_len; } cur_link->status.stats.tx_data_packets++; msg_idx++; } retry: cur = &msg[prev_sent]; sent_msgs = _sendmmsg(dst_host->link[dst_host->active_links[link_idx]].outsock, &cur[0], msgs_to_send - prev_sent, MSG_DONTWAIT | MSG_NOSIGNAL); savederrno = errno; - err = knet_h->transport_ops[dst_host->link[dst_host->active_links[link_idx]].transport_type]->transport_tx_sock_error(knet_h, dst_host->link[dst_host->active_links[link_idx]].outsock, sent_msgs, savederrno); + err = transport_tx_sock_error(knet_h, dst_host->link[dst_host->active_links[link_idx]].transport_type, dst_host->link[dst_host->active_links[link_idx]].outsock, sent_msgs, savederrno); switch(err) { case -1: /* unrecoverable error */ cur_link->status.stats.tx_data_errors++; goto out_unlock; break; case 0: /* ignore error and continue */ break; case 1: /* retry to send those same data */ cur_link->status.stats.tx_data_retries++; goto retry; break; } prev_sent = prev_sent + sent_msgs; if ((sent_msgs >= 0) && (prev_sent < msgs_to_send)) { if ((sent_msgs) || (progress)) { if (sent_msgs) { progress = 1; } else { progress = 0; } #ifdef DEBUG log_debug(knet_h, KNET_SUB_TX, "Unable to send all (%d/%d) data packets to host %s (%u) link %s:%s (%u)", sent_msgs, msg_idx, dst_host->name, dst_host->host_id, dst_host->link[dst_host->active_links[link_idx]].status.dst_ipaddr, dst_host->link[dst_host->active_links[link_idx]].status.dst_port, dst_host->link[dst_host->active_links[link_idx]].link_id); #endif goto retry; } if (!progress) { savederrno = EAGAIN; err = -1; goto out_unlock; } } if ((dst_host->link_handler_policy == KNET_LINK_POLICY_RR) && (dst_host->active_link_entries > 1)) { uint8_t cur_link_id = dst_host->active_links[0]; memmove(&dst_host->active_links[0], &dst_host->active_links[1], KNET_MAX_LINK - 1); dst_host->active_links[dst_host->active_link_entries - 1] = cur_link_id; break; } } out_unlock: errno = savederrno; return err; } static int _parse_recv_from_sock(knet_handle_t knet_h, size_t inlen, int8_t channel, int is_sync) { size_t outlen, frag_len; struct knet_host *dst_host; knet_node_id_t dst_host_ids_temp[KNET_MAX_HOST]; size_t dst_host_ids_entries_temp = 0; knet_node_id_t dst_host_ids[KNET_MAX_HOST]; size_t dst_host_ids_entries = 0; int bcast = 1; struct knet_hostinfo *knet_hostinfo; struct iovec iov_out[PCKT_FRAG_MAX][2]; int iovcnt_out = 2; uint8_t frag_idx; unsigned int temp_data_mtu; size_t host_idx; int send_mcast = 0; struct knet_header *inbuf; int savederrno = 0; int err = 0; seq_num_t tx_seq_num; struct knet_mmsghdr msg[PCKT_FRAG_MAX]; int msgs_to_send, msg_idx; unsigned int i; int j; int send_local = 0; int data_compressed = 0; size_t uncrypted_frag_size; inbuf = knet_h->recv_from_sock_buf; if ((knet_h->enabled != 1) && (inbuf->kh_type != KNET_HEADER_TYPE_HOST_INFO)) { /* data forward is disabled */ log_debug(knet_h, KNET_SUB_TX, "Received data packet but forwarding is disabled"); savederrno = ECANCELED; err = -1; goto out_unlock; } /* * move this into a separate function to expand on * extra switching rules */ switch(inbuf->kh_type) { case KNET_HEADER_TYPE_DATA: if (knet_h->dst_host_filter_fn) { bcast = knet_h->dst_host_filter_fn( knet_h->dst_host_filter_fn_private_data, (const unsigned char *)inbuf->khp_data_userdata, inlen, KNET_NOTIFY_TX, knet_h->host_id, knet_h->host_id, &channel, dst_host_ids_temp, &dst_host_ids_entries_temp); if (bcast < 0) { log_debug(knet_h, KNET_SUB_TX, "Error from dst_host_filter_fn: %d", bcast); savederrno = EFAULT; err = -1; goto out_unlock; } if ((!bcast) && (!dst_host_ids_entries_temp)) { log_debug(knet_h, KNET_SUB_TX, "Message is unicast but no dst_host_ids_entries"); savederrno = EINVAL; err = -1; goto out_unlock; } } /* Send to localhost if appropriate and enabled */ if (knet_h->has_loop_link) { send_local = 0; if (bcast) { send_local = 1; } else { for (i=0; i< dst_host_ids_entries_temp; i++) { if (dst_host_ids_temp[i] == knet_h->host_id) { send_local = 1; } } } if (send_local) { const unsigned char *buf = inbuf->khp_data_userdata; ssize_t buflen = inlen; struct knet_link *local_link; local_link = knet_h->host_index[knet_h->host_id]->link; local_retry: err = write(knet_h->sockfd[channel].sockfd[knet_h->sockfd[channel].is_created], buf, buflen); if (err < 0) { log_err(knet_h, KNET_SUB_TRANSP_LOOPBACK, "send local failed. error=%s\n", strerror(errno)); local_link->status.stats.tx_data_errors++; } if (err > 0 && err < buflen) { log_debug(knet_h, KNET_SUB_TRANSP_LOOPBACK, "send local incomplete=%d bytes of %zu\n", err, inlen); local_link->status.stats.tx_data_retries++; buf += err; buflen -= err; usleep(KNET_THREADS_TIMERES / 16); goto local_retry; } if (err == buflen) { local_link->status.stats.tx_data_packets++; local_link->status.stats.tx_data_bytes += inlen; } } } break; case KNET_HEADER_TYPE_HOST_INFO: knet_hostinfo = (struct knet_hostinfo *)inbuf->khp_data_userdata; if (knet_hostinfo->khi_bcast == KNET_HOSTINFO_UCAST) { bcast = 0; dst_host_ids_temp[0] = knet_hostinfo->khi_dst_node_id; dst_host_ids_entries_temp = 1; knet_hostinfo->khi_dst_node_id = htons(knet_hostinfo->khi_dst_node_id); } break; default: log_warn(knet_h, KNET_SUB_TX, "Receiving unknown messages from socket"); savederrno = ENOMSG; err = -1; goto out_unlock; break; } if (is_sync) { if ((bcast) || ((!bcast) && (dst_host_ids_entries_temp > 1))) { log_debug(knet_h, KNET_SUB_TX, "knet_send_sync is only supported with unicast packets for one destination"); savederrno = E2BIG; err = -1; goto out_unlock; } } /* * check destinations hosts before spending time * in fragmenting/encrypting packets to save * time processing data for unreachable hosts. * for unicast, also remap the destination data * to skip unreachable hosts. */ if (!bcast) { dst_host_ids_entries = 0; for (host_idx = 0; host_idx < dst_host_ids_entries_temp; host_idx++) { dst_host = knet_h->host_index[dst_host_ids_temp[host_idx]]; if (!dst_host) { continue; } if (!(dst_host->host_id == knet_h->host_id && knet_h->has_loop_link) && dst_host->status.reachable) { dst_host_ids[dst_host_ids_entries] = dst_host_ids_temp[host_idx]; dst_host_ids_entries++; } } if (!dst_host_ids_entries) { savederrno = EHOSTDOWN; err = -1; goto out_unlock; } } else { send_mcast = 0; for (dst_host = knet_h->host_head; dst_host != NULL; dst_host = dst_host->next) { if (!(dst_host->host_id == knet_h->host_id && knet_h->has_loop_link) && dst_host->status.reachable) { send_mcast = 1; break; } } if (!send_mcast) { savederrno = EHOSTDOWN; err = -1; goto out_unlock; } } if (!knet_h->data_mtu) { /* * using MIN_MTU_V4 for data mtu is not completely accurate but safe enough */ log_debug(knet_h, KNET_SUB_TX, "Received data packet but data MTU is still unknown." " Packet might not be delivered." " Assuming mininum IPv4 mtu (%d)", KNET_PMTUD_MIN_MTU_V4); temp_data_mtu = KNET_PMTUD_MIN_MTU_V4; } else { /* * take a copy of the mtu to avoid value changing under * our feet while we are sending a fragmented pckt */ temp_data_mtu = knet_h->data_mtu; } /* * compress data */ if ((knet_h->compress_model > 0) && (inlen > knet_h->compress_threshold)) { size_t cmp_outlen = KNET_DATABUFSIZE_COMPRESS; struct timespec start_time; struct timespec end_time; uint64_t compress_time; clock_gettime(CLOCK_MONOTONIC, &start_time); err = compress(knet_h, (const unsigned char *)inbuf->khp_data_userdata, inlen, knet_h->send_to_links_buf_compress, (ssize_t *)&cmp_outlen); if (err < 0) { log_warn(knet_h, KNET_SUB_COMPRESS, "Compression failed (%d): %s", err, strerror(errno)); } else { /* Collect stats */ clock_gettime(CLOCK_MONOTONIC, &end_time); timespec_diff(start_time, end_time, &compress_time); if (compress_time < knet_h->stats.tx_compress_time_min) { knet_h->stats.tx_compress_time_min = compress_time; } if (compress_time > knet_h->stats.tx_compress_time_max) { knet_h->stats.tx_compress_time_max = compress_time; } knet_h->stats.tx_compress_time_ave = (unsigned long long)(knet_h->stats.tx_compress_time_ave * knet_h->stats.tx_compressed_packets + compress_time) / (knet_h->stats.tx_compressed_packets+1); knet_h->stats.tx_compressed_packets++; knet_h->stats.tx_compressed_original_bytes += inlen; knet_h->stats.tx_compressed_size_bytes += cmp_outlen; if (cmp_outlen < inlen) { memmove(inbuf->khp_data_userdata, knet_h->send_to_links_buf_compress, cmp_outlen); inlen = cmp_outlen; data_compressed = 1; } } } if ((knet_h->compress_model > 0) && (inlen <= knet_h->compress_threshold)) { knet_h->stats.tx_uncompressed_packets++; } /* * prepare the outgoing buffers */ frag_len = inlen; frag_idx = 0; inbuf->khp_data_bcast = bcast; inbuf->khp_data_frag_num = ceil((float)inlen / temp_data_mtu); inbuf->khp_data_channel = channel; if (data_compressed) { inbuf->khp_data_compress = knet_h->compress_model; } else { inbuf->khp_data_compress = 0; } if (pthread_mutex_lock(&knet_h->tx_seq_num_mutex)) { log_debug(knet_h, KNET_SUB_TX, "Unable to get seq mutex lock"); goto out_unlock; } knet_h->tx_seq_num++; /* * force seq_num 0 to detect a node that has crashed and rejoining * the knet instance. seq_num 0 will clear the buffers in the RX * thread */ if (knet_h->tx_seq_num == 0) { knet_h->tx_seq_num++; } /* * cache the value in locked context */ tx_seq_num = knet_h->tx_seq_num; inbuf->khp_data_seq_num = htons(knet_h->tx_seq_num); pthread_mutex_unlock(&knet_h->tx_seq_num_mutex); /* * forcefully broadcast a ping to all nodes every SEQ_MAX / 8 * pckts. * this solves 2 problems: * 1) on TX socket overloads we generate extra pings to keep links alive * 2) in 3+ nodes setup, where all the traffic is flowing between node 1 and 2, * node 3+ will be able to keep in sync on the TX seq_num even without * receiving traffic or pings in betweens. This avoids issues with * rollover of the circular buffer */ if (tx_seq_num % (SEQ_MAX / 8) == 0) { _send_pings(knet_h, 0); } if (inbuf->khp_data_frag_num > 1) { while (frag_idx < inbuf->khp_data_frag_num) { /* * set the iov_base */ iov_out[frag_idx][0].iov_base = (void *)knet_h->send_to_links_buf[frag_idx]; iov_out[frag_idx][0].iov_len = KNET_HEADER_DATA_SIZE; iov_out[frag_idx][1].iov_base = inbuf->khp_data_userdata + (temp_data_mtu * frag_idx); /* * set the len */ if (frag_len > temp_data_mtu) { iov_out[frag_idx][1].iov_len = temp_data_mtu; } else { iov_out[frag_idx][1].iov_len = frag_len; } /* * copy the frag info on all buffers */ knet_h->send_to_links_buf[frag_idx]->kh_type = inbuf->kh_type; knet_h->send_to_links_buf[frag_idx]->khp_data_seq_num = inbuf->khp_data_seq_num; knet_h->send_to_links_buf[frag_idx]->khp_data_frag_num = inbuf->khp_data_frag_num; knet_h->send_to_links_buf[frag_idx]->khp_data_bcast = inbuf->khp_data_bcast; knet_h->send_to_links_buf[frag_idx]->khp_data_channel = inbuf->khp_data_channel; knet_h->send_to_links_buf[frag_idx]->khp_data_compress = inbuf->khp_data_compress; frag_len = frag_len - temp_data_mtu; frag_idx++; } iovcnt_out = 2; } else { iov_out[frag_idx][0].iov_base = (void *)inbuf; iov_out[frag_idx][0].iov_len = frag_len + KNET_HEADER_DATA_SIZE; iovcnt_out = 1; } if (knet_h->crypto_instance) { struct timespec start_time; struct timespec end_time; uint64_t crypt_time; frag_idx = 0; while (frag_idx < inbuf->khp_data_frag_num) { clock_gettime(CLOCK_MONOTONIC, &start_time); if (crypto_encrypt_and_signv( knet_h, iov_out[frag_idx], iovcnt_out, knet_h->send_to_links_buf_crypt[frag_idx], (ssize_t *)&outlen) < 0) { log_debug(knet_h, KNET_SUB_TX, "Unable to encrypt packet"); savederrno = ECHILD; err = -1; goto out_unlock; } clock_gettime(CLOCK_MONOTONIC, &end_time); timespec_diff(start_time, end_time, &crypt_time); if (crypt_time < knet_h->stats.tx_crypt_time_min) { knet_h->stats.tx_crypt_time_min = crypt_time; } if (crypt_time > knet_h->stats.tx_crypt_time_max) { knet_h->stats.tx_crypt_time_max = crypt_time; } knet_h->stats.tx_crypt_time_ave = (knet_h->stats.tx_crypt_time_ave * knet_h->stats.tx_crypt_packets + crypt_time) / (knet_h->stats.tx_crypt_packets+1); uncrypted_frag_size = 0; for (j=0; j < iovcnt_out; j++) { uncrypted_frag_size += iov_out[frag_idx][j].iov_len; } knet_h->stats.tx_crypt_byte_overhead += (outlen - uncrypted_frag_size); knet_h->stats.tx_crypt_packets++; iov_out[frag_idx][0].iov_base = knet_h->send_to_links_buf_crypt[frag_idx]; iov_out[frag_idx][0].iov_len = outlen; frag_idx++; } iovcnt_out = 1; } memset(&msg, 0, sizeof(msg)); msgs_to_send = inbuf->khp_data_frag_num; msg_idx = 0; while (msg_idx < msgs_to_send) { msg[msg_idx].msg_hdr.msg_namelen = sizeof(struct sockaddr_storage); msg[msg_idx].msg_hdr.msg_iov = &iov_out[msg_idx][0]; msg[msg_idx].msg_hdr.msg_iovlen = iovcnt_out; msg_idx++; } if (!bcast) { for (host_idx = 0; host_idx < dst_host_ids_entries; host_idx++) { dst_host = knet_h->host_index[dst_host_ids[host_idx]]; err = _dispatch_to_links(knet_h, dst_host, &msg[0], msgs_to_send); savederrno = errno; if (err) { goto out_unlock; } } } else { for (dst_host = knet_h->host_head; dst_host != NULL; dst_host = dst_host->next) { if (dst_host->status.reachable) { err = _dispatch_to_links(knet_h, dst_host, &msg[0], msgs_to_send); savederrno = errno; if (err) { goto out_unlock; } } } } out_unlock: errno = savederrno; return err; } int knet_send_sync(knet_handle_t knet_h, const char *buff, const size_t buff_len, const int8_t channel) { int savederrno = 0, err = 0; if (!knet_h) { errno = EINVAL; return -1; } if (buff == NULL) { errno = EINVAL; return -1; } if (buff_len <= 0) { errno = EINVAL; return -1; } if (buff_len > KNET_MAX_PACKET_SIZE) { errno = EINVAL; return -1; } if (channel < 0) { errno = EINVAL; return -1; } if (channel >= KNET_DATAFD_MAX) { errno = EINVAL; return -1; } savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_TX, "Unable to get read lock: %s", strerror(savederrno)); errno = savederrno; return -1; } if (!knet_h->sockfd[channel].in_use) { savederrno = EINVAL; err = -1; goto out; } savederrno = pthread_mutex_lock(&knet_h->tx_mutex); if (savederrno) { log_err(knet_h, KNET_SUB_TX, "Unable to get TX mutex lock: %s", strerror(savederrno)); err = -1; goto out; } knet_h->recv_from_sock_buf->kh_type = KNET_HEADER_TYPE_DATA; memmove(knet_h->recv_from_sock_buf->khp_data_userdata, buff, buff_len); err = _parse_recv_from_sock(knet_h, buff_len, channel, 1); savederrno = errno; pthread_mutex_unlock(&knet_h->tx_mutex); out: pthread_rwlock_unlock(&knet_h->global_rwlock); errno = savederrno; return err; } static void _handle_send_to_links(knet_handle_t knet_h, struct msghdr *msg, int sockfd, int8_t channel, int type) { ssize_t inlen = 0; int savederrno = 0, docallback = 0; if ((channel >= 0) && (channel < KNET_DATAFD_MAX) && (!knet_h->sockfd[channel].is_socket)) { inlen = readv(sockfd, msg->msg_iov, 1); } else { inlen = recvmsg(sockfd, msg, MSG_DONTWAIT | MSG_NOSIGNAL); } if (inlen == 0) { savederrno = 0; docallback = 1; goto out; } if (inlen < 0) { savederrno = errno; docallback = 1; goto out; } knet_h->recv_from_sock_buf->kh_type = type; _parse_recv_from_sock(knet_h, inlen, channel, 0); out: if (inlen < 0) { struct epoll_event ev; memset(&ev, 0, sizeof(struct epoll_event)); if (epoll_ctl(knet_h->send_to_links_epollfd, EPOLL_CTL_DEL, knet_h->sockfd[channel].sockfd[knet_h->sockfd[channel].is_created], &ev)) { log_err(knet_h, KNET_SUB_TX, "Unable to del datafd %d from linkfd epoll pool: %s", knet_h->sockfd[channel].sockfd[0], strerror(savederrno)); } else { knet_h->sockfd[channel].has_error = 1; } } if (docallback) { knet_h->sock_notify_fn(knet_h->sock_notify_fn_private_data, knet_h->sockfd[channel].sockfd[0], channel, KNET_NOTIFY_TX, inlen, savederrno); } } void *_handle_send_to_links_thread(void *data) { knet_handle_t knet_h = (knet_handle_t) data; struct epoll_event events[KNET_EPOLL_MAX_EVENTS]; int i, nev, type; int8_t channel; struct iovec iov_in; struct msghdr msg; struct sockaddr_storage address; memset(&iov_in, 0, sizeof(iov_in)); iov_in.iov_base = (void *)knet_h->recv_from_sock_buf->khp_data_userdata; iov_in.iov_len = KNET_MAX_PACKET_SIZE; memset(&msg, 0, sizeof(struct msghdr)); msg.msg_name = &address; msg.msg_namelen = sizeof(struct sockaddr_storage); msg.msg_iov = &iov_in; msg.msg_iovlen = 1; knet_h->recv_from_sock_buf->kh_version = KNET_HEADER_VERSION; knet_h->recv_from_sock_buf->khp_data_frag_seq = 0; knet_h->recv_from_sock_buf->kh_node = htons(knet_h->host_id); for (i = 0; i < PCKT_FRAG_MAX; i++) { knet_h->send_to_links_buf[i]->kh_version = KNET_HEADER_VERSION; knet_h->send_to_links_buf[i]->khp_data_frag_seq = i + 1; knet_h->send_to_links_buf[i]->kh_node = htons(knet_h->host_id); } while (!shutdown_in_progress(knet_h)) { nev = epoll_wait(knet_h->send_to_links_epollfd, events, KNET_EPOLL_MAX_EVENTS + 1, -1); if (pthread_rwlock_rdlock(&knet_h->global_rwlock) != 0) { log_debug(knet_h, KNET_SUB_TX, "Unable to get read lock"); continue; } for (i = 0; i < nev; i++) { if (events[i].data.fd == knet_h->hostsockfd[0]) { type = KNET_HEADER_TYPE_HOST_INFO; channel = -1; } else { type = KNET_HEADER_TYPE_DATA; for (channel = 0; channel < KNET_DATAFD_MAX; channel++) { if ((knet_h->sockfd[channel].in_use) && (knet_h->sockfd[channel].sockfd[knet_h->sockfd[channel].is_created] == events[i].data.fd)) { break; } } if (channel >= KNET_DATAFD_MAX) { log_debug(knet_h, KNET_SUB_TX, "No available channels"); continue; /* channel not found */ } } if (pthread_mutex_lock(&knet_h->tx_mutex) != 0) { log_debug(knet_h, KNET_SUB_TX, "Unable to get mutex lock"); continue; } _handle_send_to_links(knet_h, &msg, events[i].data.fd, channel, type); pthread_mutex_unlock(&knet_h->tx_mutex); } pthread_rwlock_unlock(&knet_h->global_rwlock); } return NULL; } diff --git a/libknet/transport_common.c b/libknet/transport_common.c index 2b0887a1..7269d585 100644 --- a/libknet/transport_common.c +++ b/libknet/transport_common.c @@ -1,547 +1,348 @@ /* * Copyright (C) 2016-2017 Red Hat, Inc. All rights reserved. * * Author: Fabio M. Di Nitto * * This software licensed under GPL-2.0+, LGPL-2.0+ */ #include "config.h" #include #include #include #include #include #include #include "libknet.h" #include "compat.h" #include "host.h" #include "link.h" #include "logging.h" #include "common.h" -#include "transports.h" +#include "transport_common.h" /* * reuse Jan Friesse's compat layer as wrapper to drop usage of sendmmsg * * TODO: kill those wrappers once we work on packet delivery guaranteed */ int _recvmmsg(int sockfd, struct knet_mmsghdr *msgvec, unsigned int vlen, unsigned int flags) { int savederrno = 0, err = 0; unsigned int i; for (i = 0; i < vlen; i++) { err = recvmsg(sockfd, &msgvec[i].msg_hdr, flags); savederrno = errno; if (err >= 0) { msgvec[i].msg_len = err; } else { if ((i > 0) && ((errno == EAGAIN) || (errno == EWOULDBLOCK))) { savederrno = 0; } break; } } errno = savederrno; return ((i > 0) ? (int)i : err); } int _sendmmsg(int sockfd, struct knet_mmsghdr *msgvec, unsigned int vlen, unsigned int flags) { int savederrno = 0, err = 0; unsigned int i; for (i = 0; i < vlen; i++) { err = sendmsg(sockfd, &msgvec[i].msg_hdr, flags); savederrno = errno; if (err < 0) { break; } } errno = savederrno; return ((i > 0) ? (int)i : err); } int _configure_common_socket(knet_handle_t knet_h, int sock, uint64_t flags, const char *type) { int err = 0, savederrno = 0; int value; if (_fdset_cloexec(sock)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSPORT, "Unable to set %s CLOEXEC socket opts: %s", type, strerror(savederrno)); goto exit_error; } if (_fdset_nonblock(sock)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSPORT, "Unable to set %s NONBLOCK socket opts: %s", type, strerror(savederrno)); goto exit_error; } value = KNET_RING_RCVBUFF; #ifdef SO_RCVBUFFORCE if (setsockopt(sock, SOL_SOCKET, SO_RCVBUFFORCE, &value, sizeof(value)) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSPORT, "Unable to set %s receive buffer: %s", type, strerror(savederrno)); goto exit_error; } #else if (setsockopt(sock, SOL_SOCKET, SO_RCVBUF, &value, sizeof(value)) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSPORT, "Unable to set %s SO_RECVBUF: %s", type, strerror(savederrno)); goto exit_error; } #endif value = KNET_RING_RCVBUFF; #ifdef SO_SNDBUFFORCE if (setsockopt(sock, SOL_SOCKET, SO_SNDBUFFORCE, &value, sizeof(value)) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSPORT, "Unable to set %s send buffer: %s", type, strerror(savederrno)); goto exit_error; } #else if (setsockopt(sock, SOL_SOCKET, SO_SNDBUF, &value, sizeof(value)) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSPORT, "Unable to set %s SO_SNDBUF: %s", type, strerror(savederrno)); goto exit_error; } #endif #ifdef SO_PRIORITY if (flags & KNET_LINK_FLAG_TRAFFICHIPRIO) { value = 6; /* TC_PRIO_INTERACTIVE */ if (setsockopt(sock, SOL_SOCKET, SO_PRIORITY, &value, sizeof(value)) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSPORT, "Unable to set %s priority: %s", type, strerror(savederrno)); goto exit_error; } } #endif #if defined(IP_TOS) && defined(IPTOS_LOWDELAY) if (flags & KNET_LINK_FLAG_TRAFFICHIPRIO) { value = IPTOS_LOWDELAY; if (setsockopt(sock, IPPROTO_IP, IP_TOS, &value, sizeof(value)) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSPORT, "Unable to set %s priority: %s", type, strerror(savederrno)); goto exit_error; } } #endif exit_error: errno = savederrno; return err; } int _configure_transport_socket(knet_handle_t knet_h, int sock, struct sockaddr_storage *address, uint64_t flags, const char *type) { int err = 0, savederrno = 0; int value; if (_configure_common_socket(knet_h, sock, flags, type) < 0) { savederrno = errno; err = -1; goto exit_error; } #ifdef IP_FREEBIND value = 1; if (setsockopt(sock, SOL_IP, IP_FREEBIND, &value, sizeof(value)) <0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSPORT, "Unable to set FREEBIND on %s socket: %s", type, strerror(savederrno)); goto exit_error; } #endif #ifdef IP_BINDANY /* BSD */ value = 1; if (setsockopt(sock, IPPROTO_IP, IP_BINDANY, &value, sizeof(value)) <0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSPORT, "Unable to set BINDANY on %s socket: %s", type, strerror(savederrno)); goto exit_error; } #endif if (address->ss_family == AF_INET6) { value = 1; if (setsockopt(sock, IPPROTO_IPV6, IPV6_V6ONLY, &value, sizeof(value)) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSPORT, "Unable to set %s IPv6 only: %s", type, strerror(savederrno)); goto exit_error; } #ifdef IPV6_MTU_DISCOVER value = IPV6_PMTUDISC_PROBE; if (setsockopt(sock, SOL_IPV6, IPV6_MTU_DISCOVER, &value, sizeof(value)) <0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSPORT, "Unable to set PMTUDISC on %s socket: %s", type, strerror(savederrno)); goto exit_error; } #else value = 1; if (setsockopt(sock, IPPROTO_IPV6, IPV6_DONTFRAG, &value, sizeof(value)) <0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSPORT, "Unable to set DONTFRAG on %s socket: %s", type, strerror(savederrno)); goto exit_error; } #endif } else { #ifdef IP_MTU_DISCOVER value = IP_PMTUDISC_PROBE; if (setsockopt(sock, SOL_IP, IP_MTU_DISCOVER, &value, sizeof(value)) <0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSPORT, "Unable to set PMTUDISC on %s socket: %s", type, strerror(savederrno)); goto exit_error; } #else value = 1; if (setsockopt(sock, IPPROTO_IP, IP_DONTFRAG, &value, sizeof(value)) <0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSPORT, "Unable to set DONTFRAG on %s socket: %s", type, strerror(savederrno)); goto exit_error; } #endif } value = 1; if (setsockopt(sock, SOL_SOCKET, SO_REUSEADDR, &value, sizeof(value)) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSPORT, "Unable to set %s reuseaddr: %s", type, strerror(savederrno)); goto exit_error; } exit_error: errno = savederrno; return err; } int _init_socketpair(knet_handle_t knet_h, int *sock) { int err = 0, savederrno = 0; int i; if (socketpair(AF_UNIX, SOCK_SEQPACKET, 0, sock) != 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_HANDLE, "Unable to initialize socketpair: %s", strerror(savederrno)); goto exit_fail; } for (i = 0; i < 2; i++) { if (_configure_common_socket(knet_h, sock[i], 0, "local socketpair") < 0) { savederrno = errno; err = -1; goto exit_fail; } } exit_fail: errno = savederrno; return err; } void _close_socketpair(knet_handle_t knet_h, int *sock) { int i; for (i = 0; i < 2; i++) { if (sock[i]) { close(sock[i]); sock[i] = 0; } } } /* * must be called with global read lock * * return -1 on error * return 0 if fd is invalid * return 1 if fd is valid */ int _is_valid_fd(knet_handle_t knet_h, int sockfd) { int ret = 0; if (sockfd < 0) { errno = EINVAL; return -1; } if (sockfd > KNET_MAX_FDS) { errno = EINVAL; return -1; } if (knet_h->knet_transport_fd_tracker[sockfd].transport >= KNET_MAX_TRANSPORTS) { ret = 0; } else { ret = 1; } return ret; } /* * must be called with global write lock */ int _set_fd_tracker(knet_handle_t knet_h, int sockfd, uint8_t transport, uint8_t data_type, void *data) { if (sockfd < 0) { errno = EINVAL; return -1; } if (sockfd > KNET_MAX_FDS) { errno = EINVAL; return -1; } knet_h->knet_transport_fd_tracker[sockfd].transport = transport; knet_h->knet_transport_fd_tracker[sockfd].data_type = data_type; knet_h->knet_transport_fd_tracker[sockfd].data = data; return 0; } - -/* - * public api - */ - -int knet_handle_get_transport_list(knet_handle_t knet_h, - struct knet_transport_info *transport_list, - size_t *transport_list_entries) -{ - int err = 0, savederrno = 0; - int i, count; - - if (!knet_h) { - errno = EINVAL; - return -1; - } - - if (!transport_list) { - errno = EINVAL; - return -1; - } - - if (!transport_list_entries) { - errno = EINVAL; - return -1; - } - - savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); - if (savederrno) { - log_err(knet_h, KNET_SUB_HANDLE, "Unable to get read lock: %s", - strerror(savederrno)); - errno = savederrno; - return -1; - } - - count = 0; - - /* - * we could potentially build this struct - * at knet_handle_new init time, but - * let's keep it dynamic in case at somepoint - * we need to init transports dynamically - * at runtime vs init time. - */ - - for (i=0; itransport_ops[i]) { - transport_list[count].name = knet_h->transport_ops[i]->transport_name; - transport_list[count].id = knet_h->transport_ops[i]->transport_id; - count++; - } - } - - *transport_list_entries = count; - - pthread_rwlock_unlock(&knet_h->global_rwlock); - - return err; -} - -const char *knet_handle_get_transport_name_by_id(knet_handle_t knet_h, uint8_t transport) -{ - int savederrno = 0; - const char *name = NULL; - - if (!knet_h) { - errno = EINVAL; - return name; - } - - if (transport >= KNET_MAX_TRANSPORTS) { - errno = EINVAL; - return name; - } - - savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); - if (savederrno) { - log_err(knet_h, KNET_SUB_HANDLE, "Unable to get read lock: %s", - strerror(savederrno)); - errno = savederrno; - return name; - } - - if (knet_h->transport_ops[transport]) { - name = knet_h->transport_ops[transport]->transport_name; - } else { - savederrno = ENOENT; - } - - pthread_rwlock_unlock(&knet_h->global_rwlock); - errno = savederrno; - return name; -} - -uint8_t knet_handle_get_transport_id_by_name(knet_handle_t knet_h, const char *name) -{ - int savederrno = 0; - uint8_t err = KNET_MAX_TRANSPORTS; - int i; - - if (!knet_h) { - errno = EINVAL; - return err; - } - - if (!name) { - errno = EINVAL; - return err; - } - - savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); - if (savederrno) { - log_err(knet_h, KNET_SUB_HANDLE, "Unable to get read lock: %s", - strerror(savederrno)); - errno = savederrno; - return err; - } - - for (i=0; itransport_ops[i]) { - if (!strcmp(knet_h->transport_ops[i]->transport_name, name)) { - err = knet_h->transport_ops[i]->transport_id; - break; - } - } - } - - if (err == KNET_MAX_TRANSPORTS) { - savederrno = EINVAL; - } - - pthread_rwlock_unlock(&knet_h->global_rwlock); - errno = savederrno; - return err; -} - -int knet_handle_set_transport_reconnect_interval(knet_handle_t knet_h, uint32_t msecs) -{ - int savederrno = 0; - - if (!knet_h) { - errno = EINVAL; - return -1; - } - - if (!msecs) { - errno = EINVAL; - return -1; - } - - if (msecs < 1000) { - log_warn(knet_h, KNET_SUB_HANDLE, "reconnect internval below 1 sec (%u msecs) might be too aggressive", msecs); - } - - if (msecs > 60000) { - log_warn(knet_h, KNET_SUB_HANDLE, "reconnect internval above 1 minute (%u msecs) could cause long delays in network convergiance", msecs); - } - - savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); - if (savederrno) { - log_err(knet_h, KNET_SUB_HANDLE, "Unable to get read lock: %s", - strerror(savederrno)); - errno = savederrno; - return -1; - } - - knet_h->reconnect_int = msecs; - - pthread_rwlock_unlock(&knet_h->global_rwlock); - return 0; -} - -int knet_handle_get_transport_reconnect_interval(knet_handle_t knet_h, uint32_t *msecs) -{ - int savederrno = 0; - - if (!knet_h) { - errno = EINVAL; - return -1; - } - - if (!msecs) { - errno = EINVAL; - return -1; - } - - savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); - if (savederrno) { - log_err(knet_h, KNET_SUB_HANDLE, "Unable to get read lock: %s", - strerror(savederrno)); - errno = savederrno; - return -1; - } - - *msecs = knet_h->reconnect_int; - - pthread_rwlock_unlock(&knet_h->global_rwlock); - return 0; -} diff --git a/libknet/transports.h b/libknet/transport_common.h similarity index 80% copy from libknet/transports.h copy to libknet/transport_common.h index a5158fdd..8637641d 100644 --- a/libknet/transports.h +++ b/libknet/transport_common.h @@ -1,28 +1,24 @@ /* * Copyright (C) 2016-2017 Red Hat, Inc. All rights reserved. * * Authors: Fabio M. Di Nitto * * This software licensed under GPL-2.0+, LGPL-2.0+ */ -#ifndef __KNET_TRANSPORTS_H__ -#define __KNET_TRANSPORTS_H__ - -knet_transport_ops_t *get_udp_transport(void); -knet_transport_ops_t *get_sctp_transport(void); -knet_transport_ops_t *get_loopback_transport(void); +#ifndef __KNET_TRANSPORT_COMMON_H__ +#define __KNET_TRANSPORT_COMMON_H__ int _configure_common_socket(knet_handle_t knet_h, int sock, uint64_t flags, const char *type); int _configure_transport_socket(knet_handle_t knet_h, int sock, struct sockaddr_storage *address, uint64_t flags, const char *type); int _init_socketpair(knet_handle_t knet_h, int *sock); void _close_socketpair(knet_handle_t knet_h, int *sock); int _set_fd_tracker(knet_handle_t knet_h, int sockfd, uint8_t transport, uint8_t data_type, void *data); int _is_valid_fd(knet_handle_t knet_h, int sockfd); int _sendmmsg(int sockfd, struct knet_mmsghdr *msgvec, unsigned int vlen, unsigned int flags); int _recvmmsg(int sockfd, struct knet_mmsghdr *msgvec, unsigned int vlen, unsigned int flags); #endif diff --git a/libknet/transport_loopback.c b/libknet/transport_loopback.c index a26ce758..a996edb8 100644 --- a/libknet/transport_loopback.c +++ b/libknet/transport_loopback.c @@ -1,93 +1,73 @@ /* * Copyright (C) 2017 Red Hat, Inc. All rights reserved. * * Author: Christine Caulfield * * This software licensed under GPL-2.0+, LGPL-2.0+ */ #include "config.h" #include #include #include #include #include #include #include #include #include #include "libknet.h" #include "compat.h" #include "host.h" #include "link.h" #include "logging.h" #include "common.h" #include "transports.h" +#include "transport_loopback.h" #include "threads_common.h" -#define KNET_PMTUD_LOOPBACK_OVERHEAD 0 - /* This is just a file of empty calls as the actual loopback is in threads_tx.c as a special case when receiving a packet from the localhost */ -static int loopback_transport_link_set_config(knet_handle_t knet_h, struct knet_link *kn_link) +int loopback_transport_link_set_config(knet_handle_t knet_h, struct knet_link *kn_link) { return 0; } -static int loopback_transport_link_clear_config(knet_handle_t knet_h, struct knet_link *kn_link) +int loopback_transport_link_clear_config(knet_handle_t knet_h, struct knet_link *kn_link) { return 0; } -static int loopback_transport_free(knet_handle_t knet_h) +int loopback_transport_free(knet_handle_t knet_h) { return 0; } -static int loopback_transport_init(knet_handle_t knet_h) +int loopback_transport_init(knet_handle_t knet_h) { return 0; } -static int loopback_transport_rx_sock_error(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno) +int loopback_transport_rx_sock_error(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno) { return 0; } -static int loopback_transport_tx_sock_error(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno) +int loopback_transport_tx_sock_error(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno) { return 0; } -static int loopback_transport_rx_is_data(knet_handle_t knet_h, int sockfd, struct knet_mmsghdr *msg) +int loopback_transport_rx_is_data(knet_handle_t knet_h, int sockfd, struct knet_mmsghdr *msg) { return 0; } -static int loopback_transport_link_dyn_connect(knet_handle_t knet_h, int sockfd, struct knet_link *kn_link) +int loopback_transport_link_dyn_connect(knet_handle_t knet_h, int sockfd, struct knet_link *kn_link) { return 0; } - -static knet_transport_ops_t loopback_transport_ops = { - .transport_name = "LOOPBACK", - .transport_id = KNET_TRANSPORT_LOOPBACK, - .transport_mtu_overhead = KNET_PMTUD_LOOPBACK_OVERHEAD, - .transport_init = loopback_transport_init, - .transport_free = loopback_transport_free, - .transport_link_set_config = loopback_transport_link_set_config, - .transport_link_clear_config = loopback_transport_link_clear_config, - .transport_link_dyn_connect = loopback_transport_link_dyn_connect, - .transport_rx_sock_error = loopback_transport_rx_sock_error, - .transport_tx_sock_error = loopback_transport_tx_sock_error, - .transport_rx_is_data = loopback_transport_rx_is_data, -}; - -knet_transport_ops_t *get_loopback_transport() -{ - return &loopback_transport_ops; -} diff --git a/libknet/transport_loopback.h b/libknet/transport_loopback.h new file mode 100644 index 00000000..5b7fb6c2 --- /dev/null +++ b/libknet/transport_loopback.h @@ -0,0 +1,27 @@ +/* + * Copyright (C) 2016-2017 Red Hat, Inc. All rights reserved. + * + * Authors: Fabio M. Di Nitto + * + * This software licensed under GPL-2.0+, LGPL-2.0+ + */ + +#include "config.h" + +#include "internals.h" + +#ifndef __KNET_TRANSPORT_LOOPBACK_H__ +#define __KNET_TRANSPORT_LOOPBACK_H__ + +#define KNET_PMTUD_LOOPBACK_OVERHEAD 0 + +int loopback_transport_link_set_config(knet_handle_t knet_h, struct knet_link *kn_link); +int loopback_transport_link_clear_config(knet_handle_t knet_h, struct knet_link *kn_link); +int loopback_transport_free(knet_handle_t knet_h); +int loopback_transport_init(knet_handle_t knet_h); +int loopback_transport_rx_sock_error(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno); +int loopback_transport_tx_sock_error(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno); +int loopback_transport_rx_is_data(knet_handle_t knet_h, int sockfd, struct knet_mmsghdr *msg); +int loopback_transport_link_dyn_connect(knet_handle_t knet_h, int sockfd, struct knet_link *kn_link); + +#endif diff --git a/libknet/transport_sctp.c b/libknet/transport_sctp.c index 2fed9183..4ebe74a5 100644 --- a/libknet/transport_sctp.c +++ b/libknet/transport_sctp.c @@ -1,1448 +1,1417 @@ /* * Copyright (C) 2016-2017 Red Hat, Inc. All rights reserved. * * Author: Christine Caulfield * * This software licensed under GPL-2.0+, LGPL-2.0+ */ #include "config.h" #include #include #include #include #include #include #include #include "compat.h" #include "host.h" #include "links.h" #include "logging.h" #include "common.h" -#include "transports.h" +#include "transport_common.h" #include "threads_common.h" #ifdef HAVE_NETINET_SCTP_H #include - -/* - * https://en.wikipedia.org/wiki/SCTP_packet_structure - */ -#define KNET_PMTUD_SCTP_OVERHEAD_COMMON 12 -#define KNET_PMTUD_SCTP_OVERHEAD_DATA_CHUNK 16 -#define KNET_PMTUD_SCTP_OVERHEAD KNET_PMTUD_SCTP_OVERHEAD_COMMON + KNET_PMTUD_SCTP_OVERHEAD_DATA_CHUNK +#include "transport_sctp.h" typedef struct sctp_handle_info { struct knet_list_head listen_links_list; struct knet_list_head connect_links_list; int connect_epollfd; int connectsockfd[2]; int listen_epollfd; int listensockfd[2]; pthread_t connect_thread; pthread_t listen_thread; } sctp_handle_info_t; /* * use by fd_tracker data type */ #define SCTP_NO_LINK_INFO 0 #define SCTP_LISTENER_LINK_INFO 1 #define SCTP_ACCEPTED_LINK_INFO 2 #define SCTP_CONNECT_LINK_INFO 3 /* * this value is per listener */ #define MAX_ACCEPTED_SOCKS 256 typedef struct sctp_listen_link_info { struct knet_list_head list; int listen_sock; int accepted_socks[MAX_ACCEPTED_SOCKS]; struct sockaddr_storage src_address; int on_listener_epoll; int on_rx_epoll; } sctp_listen_link_info_t; typedef struct sctp_accepted_link_info { char mread_buf[KNET_DATABUFSIZE]; ssize_t mread_len; sctp_listen_link_info_t *link_info; } sctp_accepted_link_info_t ; typedef struct sctp_connect_link_info { struct knet_list_head list; sctp_listen_link_info_t *listener; struct knet_link *link; struct sockaddr_storage dst_address; int connect_sock; int on_connected_epoll; int on_rx_epoll; int close_sock; } sctp_connect_link_info_t; /* * socket handling functions * * those functions do NOT perform locking. locking * should be handled in the right context from callers */ /* * sockets are removed from rx_epoll from callers * see also error handling functions */ static int _close_connect_socket(knet_handle_t knet_h, struct knet_link *kn_link) { int err = 0, savederrno = 0; sctp_connect_link_info_t *info = kn_link->transport_link; sctp_handle_info_t *handle_info = knet_h->transports[KNET_TRANSPORT_SCTP]; struct epoll_event ev; if (info->on_connected_epoll) { memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLOUT; ev.data.fd = info->connect_sock; if (epoll_ctl(handle_info->connect_epollfd, EPOLL_CTL_DEL, info->connect_sock, &ev)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to remove connected socket from the epoll pool: %s", strerror(errno)); goto exit_error; } info->on_connected_epoll = 0; } exit_error: if (info->connect_sock != -1) { if (_set_fd_tracker(knet_h, info->connect_sock, KNET_MAX_TRANSPORTS, SCTP_NO_LINK_INFO, NULL) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to set fd tracker: %s", strerror(savederrno)); goto exit_error; } close(info->connect_sock); info->connect_sock = -1; } errno = savederrno; return err; } static int _enable_sctp_notifications(knet_handle_t knet_h, int sock, const char *type) { int err = 0, savederrno = 0; struct sctp_event_subscribe events; memset(&events, 0, sizeof (events)); events.sctp_data_io_event = 1; events.sctp_association_event = 1; events.sctp_send_failure_event = 1; events.sctp_address_event = 1; events.sctp_peer_error_event = 1; events.sctp_shutdown_event = 1; if (setsockopt(sock, IPPROTO_SCTP, SCTP_EVENTS, &events, sizeof (events)) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to enable %s events: %s", type, strerror(savederrno)); } errno = savederrno; return err; } static int _configure_sctp_socket(knet_handle_t knet_h, int sock, struct sockaddr_storage *address, uint64_t flags, const char *type) { int err = 0, savederrno = 0; int value; int level; #ifdef SOL_SCTP level = SOL_SCTP; #else level = IPPROTO_SCTP; #endif if (_configure_transport_socket(knet_h, sock, address, flags, type) < 0) { savederrno = errno; err = -1; goto exit_error; } value = 1; if (setsockopt(sock, level, SCTP_NODELAY, &value, sizeof(value)) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSPORT, "Unable to set sctp nodelay: %s", strerror(savederrno)); goto exit_error; } if (_enable_sctp_notifications(knet_h, sock, type) < 0) { savederrno = errno; err = -1; } exit_error: errno = savederrno; return err; } static int _reconnect_socket(knet_handle_t knet_h, struct knet_link *kn_link) { int err = 0, savederrno = 0; sctp_connect_link_info_t *info = kn_link->transport_link; sctp_handle_info_t *handle_info = knet_h->transports[KNET_TRANSPORT_SCTP]; struct epoll_event ev; if (connect(info->connect_sock, (struct sockaddr *)&kn_link->dst_addr, sockaddr_len(&kn_link->dst_addr)) < 0) { if ((errno != EALREADY) && (errno != EINPROGRESS) && (errno != EISCONN)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to connect SCTP socket %d: %s", info->connect_sock, strerror(savederrno)); goto exit_error; } } if (!info->on_connected_epoll) { memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLOUT; ev.data.fd = info->connect_sock; if (epoll_ctl(handle_info->connect_epollfd, EPOLL_CTL_ADD, info->connect_sock, &ev)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to add send/recv to epoll pool: %s", strerror(savederrno)); goto exit_error; } info->on_connected_epoll = 1; } exit_error: errno = savederrno; return err; } static int _create_connect_socket(knet_handle_t knet_h, struct knet_link *kn_link) { int err = 0, savederrno = 0; sctp_connect_link_info_t *info = kn_link->transport_link; sctp_handle_info_t *handle_info = knet_h->transports[KNET_TRANSPORT_SCTP]; struct epoll_event ev; int connect_sock; connect_sock = socket(kn_link->dst_addr.ss_family, SOCK_STREAM, IPPROTO_SCTP); if (connect_sock < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to create send/recv socket: %s", strerror(savederrno)); goto exit_error; } if (_configure_sctp_socket(knet_h, connect_sock, &kn_link->dst_addr, kn_link->flags, "SCTP connect") < 0) { savederrno = errno; err = -1; goto exit_error; } if (_set_fd_tracker(knet_h, connect_sock, KNET_TRANSPORT_SCTP, SCTP_CONNECT_LINK_INFO, info) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to set fd tracker: %s", strerror(savederrno)); goto exit_error; } info->connect_sock = connect_sock; info->close_sock = 0; if (_reconnect_socket(knet_h, kn_link) < 0) { savederrno = errno; err = -1; goto exit_error; } exit_error: if (err) { if (info->on_connected_epoll) { epoll_ctl(handle_info->connect_epollfd, EPOLL_CTL_DEL, connect_sock, &ev); } if (connect_sock >= 0) { close(connect_sock); } } errno = savederrno; return err; } -static int sctp_transport_tx_sock_error(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno) +int sctp_transport_tx_sock_error(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno) { sctp_connect_link_info_t *connect_info = knet_h->knet_transport_fd_tracker[sockfd].data; sctp_accepted_link_info_t *accepted_info = knet_h->knet_transport_fd_tracker[sockfd].data; sctp_listen_link_info_t *listen_info; if (recv_err < 0) { switch (knet_h->knet_transport_fd_tracker[sockfd].data_type) { case SCTP_CONNECT_LINK_INFO: if (connect_info->link->transport_connected == 0) { return -1; } break; case SCTP_ACCEPTED_LINK_INFO: listen_info = accepted_info->link_info; if (listen_info->listen_sock != sockfd) { if (listen_info->on_rx_epoll == 0) { return -1; } } break; } if (recv_errno == EAGAIN) { #ifdef DEBUG log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Sock: %d is overloaded. Slowing TX down", sockfd); #endif /* Don't hold onto the lock while sleeping */ pthread_rwlock_unlock(&knet_h->global_rwlock); usleep(KNET_THREADS_TIMERES / 16); pthread_rwlock_rdlock(&knet_h->global_rwlock); return 1; } return -1; } return 0; } /* * socket error management functions * * both called with global read lock. * * NOTE: we need to remove the fd from the epoll as soon as possible * even before we notify the respective thread to take care of it * because scheduling can make it so that this thread will overload * and the threads supposed to take care of the error will never * be able to take action. * we CANNOT handle FDs here diretly (close/reconnect/etc) due * to locking context. We need to delegate that to their respective * management threads within global write lock. * * this function is called from: * - RX thread with recv_err <= 0 directly on recvmmsg error * - transport_rx_is_data when msg_len == 0 (recv_err = 1) * - transport_rx_is_data on notification (recv_err = 2) * * basically this small abouse of recv_err is to detect notifications * generated by sockets created by listen(). */ -static int sctp_transport_rx_sock_error(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno) +int sctp_transport_rx_sock_error(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno) { struct epoll_event ev; sctp_connect_link_info_t *connect_info = knet_h->knet_transport_fd_tracker[sockfd].data; sctp_accepted_link_info_t *accepted_info = knet_h->knet_transport_fd_tracker[sockfd].data; sctp_listen_link_info_t *listen_info; sctp_handle_info_t *handle_info = knet_h->transports[KNET_TRANSPORT_SCTP]; switch (knet_h->knet_transport_fd_tracker[sockfd].data_type) { case SCTP_CONNECT_LINK_INFO: /* * all connect link have notifications enabled * and we accept only data from notification and * generic recvmmsg errors. * * Errors generated by msg_len 0 can be ignored because * they follow a notification (double notification) */ if (recv_err != 1) { connect_info->link->transport_connected = 0; if (connect_info->on_rx_epoll) { memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLIN; ev.data.fd = sockfd; if (epoll_ctl(knet_h->recv_from_links_epollfd, EPOLL_CTL_DEL, sockfd, &ev)) { log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to remove EOFed socket from epoll pool: %s", strerror(errno)); return -1; } connect_info->on_rx_epoll = 0; } log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Notifying connect thread that sockfd %d received an error", sockfd); if (sendto(handle_info->connectsockfd[1], &sockfd, sizeof(int), MSG_DONTWAIT | MSG_NOSIGNAL, NULL, 0) != sizeof(int)) { log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to notify connect thread: %s", strerror(errno)); } } break; case SCTP_ACCEPTED_LINK_INFO: listen_info = accepted_info->link_info; if (listen_info->listen_sock != sockfd) { if (recv_err != 1) { if (listen_info->on_rx_epoll) { memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLIN; ev.data.fd = sockfd; if (epoll_ctl(knet_h->recv_from_links_epollfd, EPOLL_CTL_DEL, sockfd, &ev)) { log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to remove EOFed socket from epoll pool: %s", strerror(errno)); return -1; } listen_info->on_rx_epoll = 0; } log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Notifying listen thread that sockfd %d received an error", sockfd); if (sendto(handle_info->listensockfd[1], &sockfd, sizeof(int), MSG_DONTWAIT | MSG_NOSIGNAL, NULL, 0) != sizeof(int)) { log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to notify listen thread: %s", strerror(errno)); } } } else { /* * this means the listen() socket has generated * a notification. now what? :-) */ log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Received stray notification for listen() socket %d", sockfd); } break; default: log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Received unknown notification? %d", sockfd); break; } /* * Under RX pressure we need to give time to IPC to pick up the message */ /* Don't hold onto the lock while sleeping */ pthread_rwlock_unlock(&knet_h->global_rwlock); usleep(KNET_THREADS_TIMERES / 2); pthread_rwlock_rdlock(&knet_h->global_rwlock); return 0; } /* * NOTE: sctp_transport_rx_is_data is called with global rdlock * delegate any FD error management to sctp_transport_rx_sock_error * and keep this code to parsing incoming data only */ -static int sctp_transport_rx_is_data(knet_handle_t knet_h, int sockfd, struct knet_mmsghdr *msg) +int sctp_transport_rx_is_data(knet_handle_t knet_h, int sockfd, struct knet_mmsghdr *msg) { size_t i; struct iovec *iov = msg->msg_hdr.msg_iov; size_t iovlen = msg->msg_hdr.msg_iovlen; struct sctp_assoc_change *sac; union sctp_notification *snp; sctp_accepted_link_info_t *info = knet_h->knet_transport_fd_tracker[sockfd].data; if (!(msg->msg_hdr.msg_flags & MSG_NOTIFICATION)) { if (msg->msg_len == 0) { log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "received 0 bytes len packet: %d", sockfd); /* * NOTE: with event notification enabled, we receive error twice: * 1) from the event notification * 2) followed by a 0 byte msg_len * * This is generally not a problem if not for causing extra * handling for the same issue. Should we drop notifications * and keep the code generic (handle all errors via msg_len = 0) * or keep the duplication as safety measure, or drop msg_len = 0 * handling (what about sockets without events enabled?) */ sctp_transport_rx_sock_error(knet_h, sockfd, 1, 0); return 1; } /* * missing MSG_EOR has to be treated as a short read * from the socket and we need to fill in the mread buf * while we wait for MSG_EOR */ if (!(msg->msg_hdr.msg_flags & MSG_EOR)) { /* * copy the incoming data into mread_buf + mread_len (incremental) * and increase mread_len */ memmove(info->mread_buf + info->mread_len, iov->iov_base, msg->msg_len); info->mread_len = info->mread_len + msg->msg_len; return 0; } /* * got EOR. * if mread_len is > 0 we are completing a packet from short reads * complete reassembling the packet in mread_buf, copy it back in the iov * and set the iov/msg len numbers (size) correctly */ if (info->mread_len) { /* * add last fragment to mread_buf */ memmove(info->mread_buf + info->mread_len, iov->iov_base, msg->msg_len); info->mread_len = info->mread_len + msg->msg_len; /* * move all back into the iovec */ memmove(iov->iov_base, info->mread_buf, info->mread_len); msg->msg_len = info->mread_len; info->mread_len = 0; } return 2; } if (!(msg->msg_hdr.msg_flags & MSG_EOR)) { return 1; } for (i=0; i< iovlen; i++) { snp = iov[i].iov_base; switch (snp->sn_header.sn_type) { case SCTP_ASSOC_CHANGE: log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "[event] sctp assoc change"); sac = &snp->sn_assoc_change; if (sac->sac_state == SCTP_COMM_LOST) { log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "[event] sctp assoc change: comm_lost"); sctp_transport_rx_sock_error(knet_h, sockfd, 2, 0); } break; case SCTP_SHUTDOWN_EVENT: log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "[event] sctp shutdown event"); sctp_transport_rx_sock_error(knet_h, sockfd, 2, 0); break; case SCTP_SEND_FAILED: log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "[event] sctp send failed"); break; case SCTP_PEER_ADDR_CHANGE: log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "[event] sctp peer addr change"); break; case SCTP_REMOTE_ERROR: log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "[event] sctp remote error"); break; default: log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "[event] unknown sctp event type: %hu\n", snp->sn_header.sn_type); break; } } return 0; } /* * connect / outgoing socket management thread */ /* * _handle_connected_sctp* are called with a global write lock * from the connect_thread */ static void _handle_connected_sctp(knet_handle_t knet_h, int connect_sock) { int err; struct epoll_event ev; unsigned int status, len = sizeof(status); sctp_handle_info_t *handle_info = knet_h->transports[KNET_TRANSPORT_SCTP]; sctp_connect_link_info_t *info = knet_h->knet_transport_fd_tracker[connect_sock].data; struct knet_link *kn_link = info->link; err = getsockopt(connect_sock, SOL_SOCKET, SO_ERROR, &status, &len); if (err) { log_err(knet_h, KNET_SUB_TRANSP_SCTP, "SCTP getsockopt() on connecting socket %d failed: %s", connect_sock, strerror(errno)); return; } if (info->close_sock) { if (_close_connect_socket(knet_h, kn_link) < 0) { log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to close sock %d from _handle_connected_sctp: %s", connect_sock, strerror(errno)); return; } info->close_sock = 0; if (_create_connect_socket(knet_h, kn_link) < 0) { log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to recreate connecting sock! %s", strerror(errno)); return; } } if (status) { log_info(knet_h, KNET_SUB_TRANSP_SCTP, "SCTP connect on %d to %s port %s failed: %s", connect_sock, kn_link->status.dst_ipaddr, kn_link->status.dst_port, strerror(status)); /* * No need to create a new socket if connect failed, * just retry connect */ _reconnect_socket(knet_h, info->link); return; } /* * Connected - Remove us from the connect epoll */ memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLOUT; ev.data.fd = connect_sock; if (epoll_ctl(handle_info->connect_epollfd, EPOLL_CTL_DEL, connect_sock, &ev)) { log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to remove connected socket %d from epoll pool: %s", connect_sock, strerror(errno)); } info->on_connected_epoll = 0; kn_link->transport_connected = 1; kn_link->outsock = info->connect_sock; memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLIN; ev.data.fd = connect_sock; if (epoll_ctl(knet_h->recv_from_links_epollfd, EPOLL_CTL_ADD, connect_sock, &ev)) { log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to add connected socket to epoll pool: %s", strerror(errno)); } info->on_rx_epoll = 1; log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "SCTP handler fd %d now connected to %s port %s", connect_sock, kn_link->status.dst_ipaddr, kn_link->status.dst_port); } static void _handle_connected_sctp_errors(knet_handle_t knet_h) { int sockfd = -1; sctp_handle_info_t *handle_info = knet_h->transports[KNET_TRANSPORT_SCTP]; sctp_connect_link_info_t *info; if (recv(handle_info->connectsockfd[0], &sockfd, sizeof(int), MSG_DONTWAIT | MSG_NOSIGNAL) != sizeof(int)) { log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Short read on connectsockfd"); return; } if (_is_valid_fd(knet_h, sockfd) < 1) { log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Received stray notification for connected socket fd error"); return; } log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Processing connected error on socket: %d", sockfd); info = knet_h->knet_transport_fd_tracker[sockfd].data; info->close_sock = 1; info->link->transport_connected = 0; _reconnect_socket(knet_h, info->link); } static void *_sctp_connect_thread(void *data) { int savederrno; int i, nev; knet_handle_t knet_h = (knet_handle_t) data; sctp_handle_info_t *handle_info = knet_h->transports[KNET_TRANSPORT_SCTP]; struct epoll_event events[KNET_EPOLL_MAX_EVENTS]; while (!shutdown_in_progress(knet_h)) { nev = epoll_wait(handle_info->connect_epollfd, events, KNET_EPOLL_MAX_EVENTS, -1); if (nev < 0) { log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "SCTP connect handler EPOLL ERROR: %s", strerror(errno)); continue; } /* * Sort out which FD has a connection */ savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to get write lock: %s", strerror(savederrno)); continue; } /* * minor optimization: deduplicate events * * in some cases we can receive multiple notifcations * of the same FD having issues or need handling. * It's enough to process it once even tho it's safe * to handle them multiple times. */ for (i = 0; i < nev; i++) { if (events[i].data.fd == handle_info->connectsockfd[0]) { log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Received notification from rx_error for connected socket"); _handle_connected_sctp_errors(knet_h); } else { if (_is_valid_fd(knet_h, events[i].data.fd) == 1) { _handle_connected_sctp(knet_h, events[i].data.fd); } else { log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Received stray notification for dead fd %d\n", events[i].data.fd); } } } pthread_rwlock_unlock(&knet_h->global_rwlock); /* * this thread can generate events for itself. * we need to sleep in between loops to allow other threads * to be scheduled */ usleep(knet_h->reconnect_int * 1000); } return NULL; } /* * listen/incoming connections management thread */ /* * Listener received a new connection * called with a write lock from main thread */ static void _handle_incoming_sctp(knet_handle_t knet_h, int listen_sock) { int err = 0, savederrno = 0; int new_fd; int i = -1; sctp_listen_link_info_t *info = knet_h->knet_transport_fd_tracker[listen_sock].data; struct epoll_event ev; struct sockaddr_storage ss; socklen_t sock_len = sizeof(ss); char addr_str[KNET_MAX_HOST_LEN]; char port_str[KNET_MAX_PORT_LEN]; sctp_accepted_link_info_t *accept_info = NULL; new_fd = accept(listen_sock, (struct sockaddr *)&ss, &sock_len); if (new_fd < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Incoming: accept error: %s", strerror(errno)); goto exit_error; } if (knet_addrtostr(&ss, sizeof(ss), addr_str, KNET_MAX_HOST_LEN, port_str, KNET_MAX_PORT_LEN) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Incoming: unable to gather socket info"); goto exit_error; } log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Incoming: received connection from: %s port: %s", addr_str, port_str); /* * Keep a track of all accepted FDs */ for (i=0; iaccepted_socks[i] == -1) { info->accepted_socks[i] = new_fd; break; } } if (i == MAX_ACCEPTED_SOCKS) { errno = EBUSY; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Incoming: too many connections!"); goto exit_error; } if (_configure_common_socket(knet_h, new_fd, 0, "SCTP incoming") < 0) { /* Inherit flags from listener? */ savederrno = errno; err = -1; goto exit_error; } if (_enable_sctp_notifications(knet_h, new_fd, "Incoming connection") < 0) { savederrno = errno; err = -1; goto exit_error; } accept_info = malloc(sizeof(sctp_accepted_link_info_t)); if (!accept_info) { savederrno = errno; err = -1; goto exit_error; } memset(accept_info, 0, sizeof(sctp_accepted_link_info_t)); accept_info->link_info = info; if (_set_fd_tracker(knet_h, new_fd, KNET_TRANSPORT_SCTP, SCTP_ACCEPTED_LINK_INFO, accept_info) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to set fd tracker: %s", strerror(errno)); goto exit_error; } memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLIN; ev.data.fd = new_fd; if (epoll_ctl(knet_h->recv_from_links_epollfd, EPOLL_CTL_ADD, new_fd, &ev)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Incoming: unable to add accepted socket %d to epoll pool: %s", new_fd, strerror(errno)); goto exit_error; } info->on_rx_epoll = 1; log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Incoming: accepted new fd %d for %s/%s (listen fd: %d). index: %d", new_fd, addr_str, port_str, info->listen_sock, i); exit_error: if (err) { if ((i >= 0) || (i < MAX_ACCEPTED_SOCKS)) { info->accepted_socks[i] = -1; } _set_fd_tracker(knet_h, new_fd, KNET_MAX_TRANSPORTS, SCTP_NO_LINK_INFO, NULL); free(accept_info); close(new_fd); } errno = savederrno; return; } /* * Listen thread received a notification of a bad socket that needs closing * called with a write lock from main thread */ static void _handle_listen_sctp_errors(knet_handle_t knet_h) { int sockfd = -1; sctp_handle_info_t *handle_info = knet_h->transports[KNET_TRANSPORT_SCTP]; sctp_accepted_link_info_t *accept_info; sctp_listen_link_info_t *info; struct knet_host *host; int link_idx; int i; if (recv(handle_info->listensockfd[0], &sockfd, sizeof(int), MSG_DONTWAIT | MSG_NOSIGNAL) != sizeof(int)) { log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Short read on listensockfd"); return; } if (_is_valid_fd(knet_h, sockfd) < 1) { log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Received stray notification for listen socket fd error"); return; } log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Processing listen error on socket: %d", sockfd); accept_info = knet_h->knet_transport_fd_tracker[sockfd].data; info = accept_info->link_info; /* * clear all links using this accepted socket as * outbound dynamically connected socket */ for (host = knet_h->host_head; host != NULL; host = host->next) { for (link_idx = 0; link_idx < KNET_MAX_LINK; link_idx++) { if ((host->link[link_idx].dynamic == KNET_LINK_DYNIP) && (host->link[link_idx].outsock == sockfd)) { log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Found dynamic connection on host %d link %d (%d)", host->host_id, link_idx, sockfd); host->link[link_idx].status.dynconnected = 0; host->link[link_idx].transport_connected = 0; host->link[link_idx].outsock = 0; memset(&host->link[link_idx].dst_addr, 0, sizeof(struct sockaddr_storage)); } } } for (i=0; iaccepted_socks[i]) { log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Closing accepted socket %d", sockfd); _set_fd_tracker(knet_h, sockfd, KNET_MAX_TRANSPORTS, SCTP_NO_LINK_INFO, NULL); info->accepted_socks[i] = -1; free(accept_info); close(sockfd); } } } static void *_sctp_listen_thread(void *data) { int savederrno; int i, nev; knet_handle_t knet_h = (knet_handle_t) data; sctp_handle_info_t *handle_info = knet_h->transports[KNET_TRANSPORT_SCTP]; struct epoll_event events[KNET_EPOLL_MAX_EVENTS]; while (!shutdown_in_progress(knet_h)) { nev = epoll_wait(handle_info->listen_epollfd, events, KNET_EPOLL_MAX_EVENTS, -1); if (nev < 0) { log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "SCTP listen handler EPOLL ERROR: %s", strerror(errno)); continue; } savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); if (savederrno) { log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to get write lock: %s", strerror(savederrno)); continue; } /* * Sort out which FD has an incoming connection */ for (i = 0; i < nev; i++) { if (events[i].data.fd == handle_info->listensockfd[0]) { log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Received notification from rx_error for listener/accepted socket"); _handle_listen_sctp_errors(knet_h); } else { if (_is_valid_fd(knet_h, events[i].data.fd) == 1) { _handle_incoming_sctp(knet_h, events[i].data.fd); } else { log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Received listen notification from invalid socket"); } } } pthread_rwlock_unlock(&knet_h->global_rwlock); } return NULL; } /* * sctp_link_listener_start/stop are called in global write lock * context from set_config and clear_config. */ static sctp_listen_link_info_t *sctp_link_listener_start(knet_handle_t knet_h, struct knet_link *kn_link) { int err = 0, savederrno = 0; int listen_sock = -1; struct epoll_event ev; sctp_listen_link_info_t *info = NULL; sctp_handle_info_t *handle_info = knet_h->transports[KNET_TRANSPORT_SCTP]; /* * Only allocate a new listener if src address is different */ knet_list_for_each_entry(info, &handle_info->listen_links_list, list) { if (memcmp(&info->src_address, &kn_link->src_addr, sizeof(struct sockaddr_storage)) == 0) { return info; } } info = malloc(sizeof(sctp_listen_link_info_t)); if (!info) { err = -1; goto exit_error; } memset(info, 0, sizeof(sctp_listen_link_info_t)); memset(info->accepted_socks, -1, sizeof(info->accepted_socks)); memmove(&info->src_address, &kn_link->src_addr, sizeof(struct sockaddr_storage)); listen_sock = socket(kn_link->src_addr.ss_family, SOCK_STREAM, IPPROTO_SCTP); if (listen_sock < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to create listener socket: %s", strerror(savederrno)); goto exit_error; } if (_configure_sctp_socket(knet_h, listen_sock, &kn_link->src_addr, kn_link->flags, "SCTP listener") < 0) { savederrno = errno; err = -1; goto exit_error; } if (bind(listen_sock, (struct sockaddr *)&kn_link->src_addr, sockaddr_len(&kn_link->src_addr)) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to bind listener socket: %s", strerror(savederrno)); goto exit_error; } if (listen(listen_sock, 5) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to listen on listener socket: %s", strerror(savederrno)); goto exit_error; } if (_set_fd_tracker(knet_h, listen_sock, KNET_TRANSPORT_SCTP, SCTP_LISTENER_LINK_INFO, info) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to set fd tracker: %s", strerror(savederrno)); goto exit_error; } memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLIN; ev.data.fd = listen_sock; if (epoll_ctl(handle_info->listen_epollfd, EPOLL_CTL_ADD, listen_sock, &ev)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to add listener to epoll pool: %s", strerror(savederrno)); goto exit_error; } info->on_listener_epoll = 1; info->listen_sock = listen_sock; knet_list_add(&info->list, &handle_info->listen_links_list); log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "Listening on fd %d for %s:%s", listen_sock, kn_link->status.src_ipaddr, kn_link->status.src_port); exit_error: if (err) { if (info->on_listener_epoll) { epoll_ctl(handle_info->listen_epollfd, EPOLL_CTL_DEL, listen_sock, &ev); } if (listen_sock >= 0) { close(listen_sock); } if (info) { free(info); info = NULL; } } errno = savederrno; return info; } static int sctp_link_listener_stop(knet_handle_t knet_h, struct knet_link *kn_link) { int err = 0, savederrno = 0; int found = 0, i; struct knet_host *host; int link_idx; sctp_handle_info_t *handle_info = knet_h->transports[KNET_TRANSPORT_SCTP]; sctp_connect_link_info_t *this_link_info = kn_link->transport_link; sctp_listen_link_info_t *info = this_link_info->listener; sctp_connect_link_info_t *link_info; struct epoll_event ev; for (host = knet_h->host_head; host != NULL; host = host->next) { for (link_idx = 0; link_idx < KNET_MAX_LINK; link_idx++) { if (&host->link[link_idx] == kn_link) continue; link_info = host->link[link_idx].transport_link; if ((link_info) && (link_info->listener == info) && (host->link[link_idx].status.enabled == 1)) { found = 1; break; } } } if (found) { this_link_info->listener = NULL; log_debug(knet_h, KNET_SUB_TRANSP_SCTP, "SCTP listener socket %d still in use", info->listen_sock); savederrno = EBUSY; err = -1; goto exit_error; } if (info->on_listener_epoll) { memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLIN; ev.data.fd = info->listen_sock; if (epoll_ctl(handle_info->listen_epollfd, EPOLL_CTL_DEL, info->listen_sock, &ev)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to remove listener to epoll pool: %s", strerror(savederrno)); goto exit_error; } info->on_listener_epoll = 0; } if (_set_fd_tracker(knet_h, info->listen_sock, KNET_MAX_TRANSPORTS, SCTP_NO_LINK_INFO, NULL) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to set fd tracker: %s", strerror(savederrno)); goto exit_error; } close(info->listen_sock); for (i=0; i< MAX_ACCEPTED_SOCKS; i++) { if (info->accepted_socks[i] > -1) { memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLIN; ev.data.fd = info->accepted_socks[i]; if (epoll_ctl(knet_h->recv_from_links_epollfd, EPOLL_CTL_DEL, info->accepted_socks[i], &ev)) { log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to remove EOFed socket from epoll pool: %s", strerror(errno)); } info->on_rx_epoll = 0; free(knet_h->knet_transport_fd_tracker[info->accepted_socks[i]].data); close(info->accepted_socks[i]); if (_set_fd_tracker(knet_h, info->accepted_socks[i], KNET_MAX_TRANSPORTS, SCTP_NO_LINK_INFO, NULL) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to set fd tracker: %s", strerror(savederrno)); goto exit_error; } info->accepted_socks[i] = -1; } } knet_list_del(&info->list); free(info); this_link_info->listener = NULL; exit_error: errno = savederrno; return err; } /* * Links config/clear. Both called with global wrlock from link_set_config/clear_config */ -static int sctp_transport_link_set_config(knet_handle_t knet_h, struct knet_link *kn_link) +int sctp_transport_link_set_config(knet_handle_t knet_h, struct knet_link *kn_link) { int savederrno = 0, err = 0; sctp_connect_link_info_t *info; sctp_handle_info_t *handle_info = knet_h->transports[KNET_TRANSPORT_SCTP]; info = malloc(sizeof(sctp_connect_link_info_t)); if (!info) { goto exit_error; } memset(info, 0, sizeof(sctp_connect_link_info_t)); kn_link->transport_link = info; info->link = kn_link; memmove(&info->dst_address, &kn_link->dst_addr, sizeof(struct sockaddr_storage)); info->on_connected_epoll = 0; info->connect_sock = -1; info->listener = sctp_link_listener_start(knet_h, kn_link); if (!info->listener) { savederrno = errno; err = -1; goto exit_error; } if (kn_link->dynamic == KNET_LINK_STATIC) { if (_create_connect_socket(knet_h, kn_link) < 0) { savederrno = errno; err = -1; goto exit_error; } kn_link->outsock = info->connect_sock; } knet_list_add(&info->list, &handle_info->connect_links_list); exit_error: if (err) { if (info) { if (info->connect_sock) { close(info->connect_sock); } if (info->listener) { sctp_link_listener_stop(knet_h, kn_link); } kn_link->transport_link = NULL; free(info); } } errno = savederrno; return err; } /* * called with global wrlock */ -static int sctp_transport_link_clear_config(knet_handle_t knet_h, struct knet_link *kn_link) +int sctp_transport_link_clear_config(knet_handle_t knet_h, struct knet_link *kn_link) { int err = 0, savederrno = 0; sctp_connect_link_info_t *info; struct epoll_event ev; if (!kn_link) { errno = EINVAL; return -1; } info = kn_link->transport_link; if (!info) { errno = EINVAL; return -1; } if ((sctp_link_listener_stop(knet_h, kn_link) <0) && (errno != EBUSY)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to remove listener trasport: %s", strerror(savederrno)); goto exit_error; } if (info->on_rx_epoll) { memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLIN; ev.data.fd = info->connect_sock; if (epoll_ctl(knet_h->recv_from_links_epollfd, EPOLL_CTL_DEL, info->connect_sock, &ev)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to remove connected socket from epoll pool: %s", strerror(savederrno)); goto exit_error; } info->on_rx_epoll = 0; } if (_close_connect_socket(knet_h, kn_link) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to close connected socket: %s", strerror(savederrno)); goto exit_error; } knet_list_del(&info->list); free(info); kn_link->transport_link = NULL; exit_error: errno = savederrno; return err; } /* * transport_free and transport_init are * called only from knet_handle_new and knet_handle_free. * all resources (hosts/links) should have been already freed at this point * and they are called in a write locked context, hence they * don't need their own locking. */ -static int sctp_transport_free(knet_handle_t knet_h) +int sctp_transport_free(knet_handle_t knet_h) { sctp_handle_info_t *handle_info; void *thread_status; struct epoll_event ev; if (!knet_h->transports[KNET_TRANSPORT_SCTP]) { errno = EINVAL; return -1; } handle_info = knet_h->transports[KNET_TRANSPORT_SCTP]; /* * keep it here while we debug list usage and such */ if (!knet_list_empty(&handle_info->listen_links_list)) { log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Internal error. listen links list is not empty"); } if (!knet_list_empty(&handle_info->connect_links_list)) { log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Internal error. connect links list is not empty"); } if (handle_info->listen_thread) { pthread_cancel(handle_info->listen_thread); pthread_join(handle_info->listen_thread, &thread_status); } if (handle_info->connect_thread) { pthread_cancel(handle_info->connect_thread); pthread_join(handle_info->connect_thread, &thread_status); } if (handle_info->listensockfd[0] >= 0) { memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLIN; ev.data.fd = handle_info->listensockfd[0]; epoll_ctl(handle_info->listen_epollfd, EPOLL_CTL_DEL, handle_info->listensockfd[0], &ev); } if (handle_info->connectsockfd[0] >= 0) { memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLIN; ev.data.fd = handle_info->connectsockfd[0]; epoll_ctl(handle_info->connect_epollfd, EPOLL_CTL_DEL, handle_info->connectsockfd[0], &ev); } _close_socketpair(knet_h, handle_info->connectsockfd); _close_socketpair(knet_h, handle_info->listensockfd); if (handle_info->listen_epollfd >= 0) { close(handle_info->listen_epollfd); } if (handle_info->connect_epollfd >= 0) { close(handle_info->connect_epollfd); } free(handle_info); knet_h->transports[KNET_TRANSPORT_SCTP] = NULL; return 0; } -static int sctp_transport_init(knet_handle_t knet_h) +int sctp_transport_init(knet_handle_t knet_h) { int err = 0, savederrno = 0; sctp_handle_info_t *handle_info; struct epoll_event ev; if (knet_h->transports[KNET_TRANSPORT_SCTP]) { errno = EEXIST; return -1; } handle_info = malloc(sizeof(sctp_handle_info_t)); if (!handle_info) { return -1; } memset(handle_info, 0,sizeof(sctp_handle_info_t)); knet_h->transports[KNET_TRANSPORT_SCTP] = handle_info; knet_list_init(&handle_info->listen_links_list); knet_list_init(&handle_info->connect_links_list); handle_info->listen_epollfd = epoll_create(KNET_EPOLL_MAX_EVENTS + 1); if (handle_info->listen_epollfd < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to create epoll listen fd: %s", strerror(savederrno)); goto exit_fail; } if (_fdset_cloexec(handle_info->listen_epollfd)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to set CLOEXEC on listen_epollfd: %s", strerror(savederrno)); goto exit_fail; } handle_info->connect_epollfd = epoll_create(KNET_EPOLL_MAX_EVENTS + 1); if (handle_info->connect_epollfd < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to create epoll connect fd: %s", strerror(savederrno)); goto exit_fail; } if (_fdset_cloexec(handle_info->connect_epollfd)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to set CLOEXEC on connect_epollfd: %s", strerror(savederrno)); goto exit_fail; } if (_init_socketpair(knet_h, handle_info->connectsockfd) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to init connect socketpair: %s", strerror(savederrno)); goto exit_fail; } memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLIN; ev.data.fd = handle_info->connectsockfd[0]; if (epoll_ctl(handle_info->connect_epollfd, EPOLL_CTL_ADD, handle_info->connectsockfd[0], &ev)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to add connectsockfd[0] to connect epoll pool: %s", strerror(savederrno)); goto exit_fail; } if (_init_socketpair(knet_h, handle_info->listensockfd) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to init listen socketpair: %s", strerror(savederrno)); goto exit_fail; } memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLIN; ev.data.fd = handle_info->listensockfd[0]; if (epoll_ctl(handle_info->listen_epollfd, EPOLL_CTL_ADD, handle_info->listensockfd[0], &ev)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to add listensockfd[0] to listen epoll pool: %s", strerror(savederrno)); goto exit_fail; } /* * Start connect & listener threads */ savederrno = pthread_create(&handle_info->listen_thread, 0, _sctp_listen_thread, (void *) knet_h); if (savederrno) { err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to start sctp listen thread: %s", strerror(savederrno)); goto exit_fail; } savederrno = pthread_create(&handle_info->connect_thread, 0, _sctp_connect_thread, (void *) knet_h); if (savederrno) { err = -1; log_err(knet_h, KNET_SUB_TRANSP_SCTP, "Unable to start sctp connect thread: %s", strerror(savederrno)); goto exit_fail; } exit_fail: if (err < 0) { sctp_transport_free(knet_h); } errno = savederrno; return err; } -static int sctp_transport_link_dyn_connect(knet_handle_t knet_h, int sockfd, struct knet_link *kn_link) +int sctp_transport_link_dyn_connect(knet_handle_t knet_h, int sockfd, struct knet_link *kn_link) { kn_link->outsock = sockfd; kn_link->status.dynconnected = 1; kn_link->transport_connected = 1; return 0; } - -static knet_transport_ops_t sctp_transport_ops = { - .transport_name = "SCTP", - .transport_id = KNET_TRANSPORT_SCTP, - .transport_mtu_overhead = KNET_PMTUD_SCTP_OVERHEAD, - .transport_init = sctp_transport_init, - .transport_free = sctp_transport_free, - .transport_link_set_config = sctp_transport_link_set_config, - .transport_link_clear_config = sctp_transport_link_clear_config, - .transport_link_dyn_connect = sctp_transport_link_dyn_connect, - .transport_rx_sock_error = sctp_transport_rx_sock_error, - .transport_tx_sock_error = sctp_transport_tx_sock_error, - .transport_rx_is_data = sctp_transport_rx_is_data, -}; - -knet_transport_ops_t *get_sctp_transport() -{ - - return &sctp_transport_ops; -} -#else // HAVE_NETINET_SCTP_H -knet_transport_ops_t *get_sctp_transport() -{ - return NULL; -} #endif diff --git a/libknet/transport_sctp.h b/libknet/transport_sctp.h new file mode 100644 index 00000000..9565f6e6 --- /dev/null +++ b/libknet/transport_sctp.h @@ -0,0 +1,37 @@ +/* + * Copyright (C) 2016-2017 Red Hat, Inc. All rights reserved. + * + * Authors: Fabio M. Di Nitto + * + * This software licensed under GPL-2.0+, LGPL-2.0+ + */ + +#include "config.h" + +#include "internals.h" + +#ifndef __KNET_TRANSPORT_SCTP_H__ +#define __KNET_TRANSPORT_SCTP_H__ + +/* + * https://en.wikipedia.org/wiki/SCTP_packet_structure + */ + +#define KNET_PMTUD_SCTP_OVERHEAD_COMMON 12 +#define KNET_PMTUD_SCTP_OVERHEAD_DATA_CHUNK 16 +#define KNET_PMTUD_SCTP_OVERHEAD KNET_PMTUD_SCTP_OVERHEAD_COMMON + KNET_PMTUD_SCTP_OVERHEAD_DATA_CHUNK + +#ifdef HAVE_NETINET_SCTP_H + +int sctp_transport_link_set_config(knet_handle_t knet_h, struct knet_link *kn_link); +int sctp_transport_link_clear_config(knet_handle_t knet_h, struct knet_link *kn_link); +int sctp_transport_free(knet_handle_t knet_h); +int sctp_transport_init(knet_handle_t knet_h); +int sctp_transport_rx_sock_error(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno); +int sctp_transport_tx_sock_error(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno); +int sctp_transport_rx_is_data(knet_handle_t knet_h, int sockfd, struct knet_mmsghdr *msg); +int sctp_transport_link_dyn_connect(knet_handle_t knet_h, int sockfd, struct knet_link *kn_link); + +#endif + +#endif diff --git a/libknet/transport_udp.c b/libknet/transport_udp.c index d5dd7058..2ad0392c 100644 --- a/libknet/transport_udp.c +++ b/libknet/transport_udp.c @@ -1,416 +1,396 @@ /* * Copyright (C) 2016-2017 Red Hat, Inc. All rights reserved. * * Author: Christine Caulfield * * This software licensed under GPL-2.0+, LGPL-2.0+ */ #include "config.h" #include #include #include #include #include #include #include #include #include #if defined (IP_RECVERR) || defined (IPV6_RECVERR) #include #endif #include "libknet.h" #include "compat.h" #include "host.h" #include "link.h" #include "logging.h" #include "common.h" -#include "transports.h" +#include "transport_common.h" +#include "transport_udp.h" #include "threads_common.h" -#define KNET_PMTUD_UDP_OVERHEAD 8 - typedef struct udp_handle_info { struct knet_list_head links_list; } udp_handle_info_t; typedef struct udp_link_info { struct knet_list_head list; struct sockaddr_storage local_address; int socket_fd; int on_epoll; } udp_link_info_t; -static int udp_transport_link_set_config(knet_handle_t knet_h, struct knet_link *kn_link) +int udp_transport_link_set_config(knet_handle_t knet_h, struct knet_link *kn_link) { int err = 0, savederrno = 0; int sock = -1; struct epoll_event ev; udp_link_info_t *info; udp_handle_info_t *handle_info = knet_h->transports[KNET_TRANSPORT_UDP]; #if defined (IP_RECVERR) || defined (IPV6_RECVERR) int value; #endif /* * Only allocate a new link if the local address is different */ knet_list_for_each_entry(info, &handle_info->links_list, list) { if (memcmp(&info->local_address, &kn_link->src_addr, sizeof(struct sockaddr_storage)) == 0) { log_debug(knet_h, KNET_SUB_TRANSP_UDP, "Re-using existing UDP socket for new link"); kn_link->outsock = info->socket_fd; kn_link->transport_link = info; kn_link->transport_connected = 1; return 0; } } info = malloc(sizeof(udp_link_info_t)); if (!info) { err = -1; goto exit_error; } sock = socket(kn_link->src_addr.ss_family, SOCK_DGRAM, 0); if (sock < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_LISTENER, "Unable to create listener socket: %s", strerror(savederrno)); goto exit_error; } if (_configure_transport_socket(knet_h, sock, &kn_link->src_addr, kn_link->flags, "UDP") < 0) { savederrno = errno; err = -1; goto exit_error; } #ifdef IP_RECVERR if (kn_link->src_addr.ss_family == AF_INET) { value = 1; if (setsockopt(sock, SOL_IP, IP_RECVERR, &value, sizeof(value)) <0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_UDP, "Unable to set RECVERR on socket: %s", strerror(savederrno)); goto exit_error; } } #endif #ifdef IPV6_RECVERR if (kn_link->src_addr.ss_family == AF_INET6) { value = 1; if (setsockopt(sock, SOL_IPV6, IPV6_RECVERR, &value, sizeof(value)) <0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_UDP, "Unable to set RECVERR on socket: %s", strerror(savederrno)); goto exit_error; } } #endif if (bind(sock, (struct sockaddr *)&kn_link->src_addr, sockaddr_len(&kn_link->src_addr))) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_UDP, "Unable to bind listener socket: %s", strerror(savederrno)); goto exit_error; } memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLIN; ev.data.fd = sock; if (epoll_ctl(knet_h->recv_from_links_epollfd, EPOLL_CTL_ADD, sock, &ev)) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_UDP, "Unable to add listener to epoll pool: %s", strerror(savederrno)); goto exit_error; } info->on_epoll = 1; if (_set_fd_tracker(knet_h, sock, KNET_TRANSPORT_UDP, 0, info) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_UDP, "Unable to set fd tracker: %s", strerror(savederrno)); goto exit_error; } memmove(&info->local_address, &kn_link->src_addr, sizeof(struct sockaddr_storage)); info->socket_fd = sock; knet_list_add(&info->list, &handle_info->links_list); kn_link->outsock = sock; kn_link->transport_link = info; kn_link->transport_connected = 1; exit_error: if (err) { if (info) { if (info->on_epoll) { epoll_ctl(knet_h->recv_from_links_epollfd, EPOLL_CTL_DEL, sock, &ev); } free(info); } if (sock >= 0) { close(sock); } } errno = savederrno; return err; } -static int udp_transport_link_clear_config(knet_handle_t knet_h, struct knet_link *kn_link) +int udp_transport_link_clear_config(knet_handle_t knet_h, struct knet_link *kn_link) { int err = 0, savederrno = 0; int found = 0; struct knet_host *host; int link_idx; udp_link_info_t *info = kn_link->transport_link; struct epoll_event ev; for (host = knet_h->host_head; host != NULL; host = host->next) { for (link_idx = 0; link_idx < KNET_MAX_LINK; link_idx++) { if (&host->link[link_idx] == kn_link) continue; if ((host->link[link_idx].transport_link == info) && (host->link[link_idx].status.enabled == 1)) { found = 1; break; } } } if (found) { log_debug(knet_h, KNET_SUB_TRANSP_UDP, "UDP socket %d still in use", info->socket_fd); savederrno = EBUSY; err = -1; goto exit_error; } if (info->on_epoll) { memset(&ev, 0, sizeof(struct epoll_event)); ev.events = EPOLLIN; ev.data.fd = info->socket_fd; if (epoll_ctl(knet_h->recv_from_links_epollfd, EPOLL_CTL_DEL, info->socket_fd, &ev) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_UDP, "Unable to remove UDP socket from epoll poll: %s", strerror(errno)); goto exit_error; } info->on_epoll = 0; } if (_set_fd_tracker(knet_h, info->socket_fd, KNET_MAX_TRANSPORTS, 0, NULL) < 0) { savederrno = errno; err = -1; log_err(knet_h, KNET_SUB_TRANSP_UDP, "Unable to set fd tracker: %s", strerror(savederrno)); goto exit_error; } close(info->socket_fd); knet_list_del(&info->list); free(kn_link->transport_link); exit_error: errno = savederrno; return err; } -static int udp_transport_free(knet_handle_t knet_h) +int udp_transport_free(knet_handle_t knet_h) { udp_handle_info_t *handle_info; if (!knet_h->transports[KNET_TRANSPORT_UDP]) { errno = EINVAL; return -1; } handle_info = knet_h->transports[KNET_TRANSPORT_UDP]; /* * keep it here while we debug list usage and such */ if (!knet_list_empty(&handle_info->links_list)) { log_err(knet_h, KNET_SUB_TRANSP_UDP, "Internal error. handle list is not empty"); return -1; } free(handle_info); knet_h->transports[KNET_TRANSPORT_UDP] = NULL; return 0; } -static int udp_transport_init(knet_handle_t knet_h) +int udp_transport_init(knet_handle_t knet_h) { udp_handle_info_t *handle_info; if (knet_h->transports[KNET_TRANSPORT_UDP]) { errno = EEXIST; return -1; } handle_info = malloc(sizeof(udp_handle_info_t)); if (!handle_info) { return -1; } memset(handle_info, 0, sizeof(udp_handle_info_t)); knet_h->transports[KNET_TRANSPORT_UDP] = handle_info; knet_list_init(&handle_info->links_list); return 0; } #if defined (IP_RECVERR) || defined (IPV6_RECVERR) static int read_errs_from_sock(knet_handle_t knet_h, int sockfd) { int err = 0, savederrno = 0; int got_err = 0; char buffer[1024]; struct iovec iov; struct msghdr msg; struct cmsghdr *cmsg; struct sock_extended_err *sock_err; struct icmphdr icmph; struct sockaddr_storage remote; struct sockaddr_storage *origin; char addr_str[KNET_MAX_HOST_LEN]; char port_str[KNET_MAX_PORT_LEN]; iov.iov_base = &icmph; iov.iov_len = sizeof(icmph); msg.msg_name = (void*)&remote; msg.msg_namelen = sizeof(remote); msg.msg_iov = &iov; msg.msg_iovlen = 1; msg.msg_flags = 0; msg.msg_control = buffer; msg.msg_controllen = sizeof(buffer); for (;;) { err = recvmsg(sockfd, &msg, MSG_ERRQUEUE); savederrno = errno; if (err < 0) { if (!got_err) { errno = savederrno; return -1; } else { return 0; } } got_err = 1; for (cmsg = CMSG_FIRSTHDR(&msg);cmsg; cmsg = CMSG_NXTHDR(&msg, cmsg)) { if (((cmsg->cmsg_level == SOL_IP) && (cmsg->cmsg_type == IP_RECVERR)) || ((cmsg->cmsg_level == SOL_IPV6 && (cmsg->cmsg_type == IPV6_RECVERR)))) { sock_err = (struct sock_extended_err*)(void *)CMSG_DATA(cmsg); if (sock_err) { switch (sock_err->ee_origin) { case 0: /* no origin */ case 1: /* local source (EMSGSIZE) */ /* * those errors are way too noisy */ break; case 2: /* ICMP */ case 3: /* ICMP6 */ origin = (struct sockaddr_storage *)(void *)SO_EE_OFFENDER(sock_err); if (knet_addrtostr(origin, sizeof(origin), addr_str, KNET_MAX_HOST_LEN, port_str, KNET_MAX_PORT_LEN) < 0) { log_debug(knet_h, KNET_SUB_TRANSP_UDP, "Received ICMP error from unknown source: %s", strerror(sock_err->ee_errno)); } else { log_debug(knet_h, KNET_SUB_TRANSP_UDP, "Received ICMP error from %s: %s", addr_str, strerror(sock_err->ee_errno)); } break; } } else { log_debug(knet_h, KNET_SUB_TRANSP_UDP, "No data in MSG_ERRQUEUE"); } } } } } #else static int read_errs_from_sock(knet_handle_t knet_h, int sockfd) { return 0; } #endif -static int udp_transport_rx_sock_error(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno) +int udp_transport_rx_sock_error(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno) { if (recv_errno == EAGAIN) { read_errs_from_sock(knet_h, sockfd); } return 0; } -static int udp_transport_tx_sock_error(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno) +int udp_transport_tx_sock_error(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno) { if (recv_err < 0) { if (recv_errno == EMSGSIZE) { return 0; } if ((recv_errno == ENOBUFS) || (recv_errno == EAGAIN)) { #ifdef DEBUG log_debug(knet_h, KNET_SUB_TRANSP_UDP, "Sock: %d is overloaded. Slowing TX down", sockfd); #endif usleep(KNET_THREADS_TIMERES / 16); } else { read_errs_from_sock(knet_h, sockfd); } return 1; } return 0; } -static int udp_transport_rx_is_data(knet_handle_t knet_h, int sockfd, struct knet_mmsghdr *msg) +int udp_transport_rx_is_data(knet_handle_t knet_h, int sockfd, struct knet_mmsghdr *msg) { if (msg->msg_len == 0) return 0; return 2; } -static int udp_transport_link_dyn_connect(knet_handle_t knet_h, int sockfd, struct knet_link *kn_link) +int udp_transport_link_dyn_connect(knet_handle_t knet_h, int sockfd, struct knet_link *kn_link) { kn_link->status.dynconnected = 1; return 0; } - -static knet_transport_ops_t udp_transport_ops = { - .transport_name = "UDP", - .transport_id = KNET_TRANSPORT_UDP, - .transport_mtu_overhead = KNET_PMTUD_UDP_OVERHEAD, - .transport_init = udp_transport_init, - .transport_free = udp_transport_free, - .transport_link_set_config = udp_transport_link_set_config, - .transport_link_clear_config = udp_transport_link_clear_config, - .transport_link_dyn_connect = udp_transport_link_dyn_connect, - .transport_rx_sock_error = udp_transport_rx_sock_error, - .transport_tx_sock_error = udp_transport_tx_sock_error, - .transport_rx_is_data = udp_transport_rx_is_data, -}; - -knet_transport_ops_t *get_udp_transport() -{ - return &udp_transport_ops; -} diff --git a/libknet/transport_udp.h b/libknet/transport_udp.h new file mode 100644 index 00000000..1d886bde --- /dev/null +++ b/libknet/transport_udp.h @@ -0,0 +1,27 @@ +/* + * Copyright (C) 2016-2017 Red Hat, Inc. All rights reserved. + * + * Authors: Fabio M. Di Nitto + * + * This software licensed under GPL-2.0+, LGPL-2.0+ + */ + +#include "config.h" + +#include "internals.h" + +#ifndef __KNET_TRANSPORT_UDP_H__ +#define __KNET_TRANSPORT_UDP_H__ + +#define KNET_PMTUD_UDP_OVERHEAD 8 + +int udp_transport_link_set_config(knet_handle_t knet_h, struct knet_link *kn_link); +int udp_transport_link_clear_config(knet_handle_t knet_h, struct knet_link *kn_link); +int udp_transport_free(knet_handle_t knet_h); +int udp_transport_init(knet_handle_t knet_h); +int udp_transport_rx_sock_error(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno); +int udp_transport_tx_sock_error(knet_handle_t knet_h, int sockfd, int recv_err, int recv_errno); +int udp_transport_rx_is_data(knet_handle_t knet_h, int sockfd, struct knet_mmsghdr *msg); +int udp_transport_link_dyn_connect(knet_handle_t knet_h, int sockfd, struct knet_link *kn_link); + +#endif diff --git a/libknet/transports.c b/libknet/transports.c new file mode 100644 index 00000000..da06baf0 --- /dev/null +++ b/libknet/transports.c @@ -0,0 +1,316 @@ +/* + * Copyright (C) 2016-2017 Red Hat, Inc. All rights reserved. + * + * Author: Fabio M. Di Nitto + * + * This software licensed under GPL-2.0+, LGPL-2.0+ + */ + +#include "config.h" + +#include +#include +#include +#include +#include +#include + +#include "libknet.h" +#include "compat.h" +#include "host.h" +#include "link.h" +#include "logging.h" +#include "common.h" +#include "transports.h" +#include "transport_loopback.h" +#include "transport_udp.h" +#include "transport_sctp.h" + +#define empty_module 0, 0, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL }, + +knet_transport_ops_t transport_modules_cmd[] = { + { "LOOPBACK", KNET_TRANSPORT_LOOPBACK, 1, KNET_PMTUD_LOOPBACK_OVERHEAD, loopback_transport_init, loopback_transport_free, loopback_transport_link_set_config, loopback_transport_link_clear_config, loopback_transport_link_dyn_connect, loopback_transport_rx_sock_error, loopback_transport_tx_sock_error, loopback_transport_rx_is_data }, + { "UDP", KNET_TRANSPORT_UDP, 1, KNET_PMTUD_UDP_OVERHEAD, udp_transport_init, udp_transport_free, udp_transport_link_set_config, udp_transport_link_clear_config, udp_transport_link_dyn_connect, udp_transport_rx_sock_error, udp_transport_tx_sock_error, udp_transport_rx_is_data }, + { "SCTP", KNET_TRANSPORT_SCTP, +#ifdef HAVE_NETINET_SCTP_H + 1, KNET_PMTUD_SCTP_OVERHEAD, sctp_transport_init, sctp_transport_free, sctp_transport_link_set_config, sctp_transport_link_clear_config, sctp_transport_link_dyn_connect, sctp_transport_rx_sock_error, sctp_transport_tx_sock_error, sctp_transport_rx_is_data }, +#else +empty_module +#endif + { NULL, KNET_MAX_TRANSPORTS, empty_module +}; + +/* + * transport wrappers + */ + +int start_all_transports(knet_handle_t knet_h) +{ + int idx = 0, savederrno = 0, err = 0; + + while (transport_modules_cmd[idx].transport_name != NULL) { + if (transport_modules_cmd[idx].built_in) { + if (transport_modules_cmd[idx].transport_init(knet_h) < 0) { + savederrno = errno; + log_err(knet_h, KNET_SUB_HANDLE, + "Failed to allocate transport handle for %s: %s", + transport_modules_cmd[idx].transport_name, + strerror(savederrno)); + err = -1; + goto out; + } + } + idx++; + } + +out: + errno = savederrno; + return err; +} + +void stop_all_transports(knet_handle_t knet_h) +{ + int idx = 0; + + while (transport_modules_cmd[idx].transport_name != NULL) { + if (transport_modules_cmd[idx].built_in) { + transport_modules_cmd[idx].transport_free(knet_h); + } + idx++; + } +} + +int transport_link_set_config(knet_handle_t knet_h, struct knet_link *kn_link, uint8_t transport) +{ + if (!transport_modules_cmd[transport].built_in) { + errno = EINVAL; + return -1; + } + kn_link->transport_connected = 0; + kn_link->transport_type = transport; + kn_link->proto_overhead = transport_modules_cmd[transport].transport_mtu_overhead; + return transport_modules_cmd[transport].transport_link_set_config(knet_h, kn_link); +} + +int transport_link_clear_config(knet_handle_t knet_h, struct knet_link *kn_link) +{ + return transport_modules_cmd[kn_link->transport_type].transport_link_clear_config(knet_h, kn_link); +} + +int transport_link_dyn_connect(knet_handle_t knet_h, int sockfd, struct knet_link *kn_link) +{ + return transport_modules_cmd[kn_link->transport_type].transport_link_dyn_connect(knet_h, sockfd, kn_link); +} + +int transport_rx_sock_error(knet_handle_t knet_h, uint8_t transport, int sockfd, int recv_err, int recv_errno) +{ + return transport_modules_cmd[transport].transport_rx_sock_error(knet_h, sockfd, recv_err, recv_errno); +} + +int transport_tx_sock_error(knet_handle_t knet_h, uint8_t transport, int sockfd, int recv_err, int recv_errno) +{ + return transport_modules_cmd[transport].transport_tx_sock_error(knet_h, sockfd, recv_err, recv_errno); +} + +int transport_rx_is_data(knet_handle_t knet_h, uint8_t transport, int sockfd, struct knet_mmsghdr *msg) +{ + return transport_modules_cmd[transport].transport_rx_is_data(knet_h, sockfd, msg); +} + +/* + * public api + */ + +int knet_handle_get_transport_list(knet_handle_t knet_h, + struct knet_transport_info *transport_list, + size_t *transport_list_entries) +{ + int err = 0, savederrno = 0; + int i, count; + + if (!knet_h) { + errno = EINVAL; + return -1; + } + + if (!transport_list) { + errno = EINVAL; + return -1; + } + + if (!transport_list_entries) { + errno = EINVAL; + return -1; + } + + savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); + if (savederrno) { + log_err(knet_h, KNET_SUB_HANDLE, "Unable to get read lock: %s", + strerror(savederrno)); + errno = savederrno; + return -1; + } + + count = 0; + i = 0; + + while (transport_modules_cmd[i].transport_name != NULL) { + if (transport_modules_cmd[i].built_in) { + transport_list[count].name = transport_modules_cmd[i].transport_name; + transport_list[count].id = transport_modules_cmd[i].transport_id; + count++; + } + i++; + } + + *transport_list_entries = count; + + pthread_rwlock_unlock(&knet_h->global_rwlock); + + return err; +} + +const char *knet_handle_get_transport_name_by_id(knet_handle_t knet_h, uint8_t transport) +{ + int savederrno = 0; + const char *name = NULL; + + if (!knet_h) { + errno = EINVAL; + return name; + } + + if (transport >= KNET_MAX_TRANSPORTS) { + errno = EINVAL; + return name; + } + + savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); + if (savederrno) { + log_err(knet_h, KNET_SUB_HANDLE, "Unable to get read lock: %s", + strerror(savederrno)); + errno = savederrno; + return name; + } + + if ((transport_modules_cmd[transport].transport_name) && + (transport_modules_cmd[transport].built_in)) { + name = transport_modules_cmd[transport].transport_name; + } else { + savederrno = ENOENT; + } + + pthread_rwlock_unlock(&knet_h->global_rwlock); + errno = savederrno; + return name; +} + +uint8_t knet_handle_get_transport_id_by_name(knet_handle_t knet_h, const char *name) +{ + int savederrno = 0; + uint8_t err = KNET_MAX_TRANSPORTS; + int i, found; + + if (!knet_h) { + errno = EINVAL; + return err; + } + + if (!name) { + errno = EINVAL; + return err; + } + + savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); + if (savederrno) { + log_err(knet_h, KNET_SUB_HANDLE, "Unable to get read lock: %s", + strerror(savederrno)); + errno = savederrno; + return err; + } + + i = 0; + found = 0; + while (transport_modules_cmd[i].transport_name != NULL) { + if (transport_modules_cmd[i].built_in) { + if (!strcmp(transport_modules_cmd[i].transport_name, name)) { + err = transport_modules_cmd[i].transport_id; + found = 1; + break; + } + } + i++; + } + + if (!found) { + savederrno = EINVAL; + } + + pthread_rwlock_unlock(&knet_h->global_rwlock); + errno = savederrno; + return err; +} + +int knet_handle_set_transport_reconnect_interval(knet_handle_t knet_h, uint32_t msecs) +{ + int savederrno = 0; + + if (!knet_h) { + errno = EINVAL; + return -1; + } + + if (!msecs) { + errno = EINVAL; + return -1; + } + + if (msecs < 1000) { + log_warn(knet_h, KNET_SUB_HANDLE, "reconnect internval below 1 sec (%u msecs) might be too aggressive", msecs); + } + + if (msecs > 60000) { + log_warn(knet_h, KNET_SUB_HANDLE, "reconnect internval above 1 minute (%u msecs) could cause long delays in network convergiance", msecs); + } + + savederrno = pthread_rwlock_wrlock(&knet_h->global_rwlock); + if (savederrno) { + log_err(knet_h, KNET_SUB_HANDLE, "Unable to get read lock: %s", + strerror(savederrno)); + errno = savederrno; + return -1; + } + + knet_h->reconnect_int = msecs; + + pthread_rwlock_unlock(&knet_h->global_rwlock); + return 0; +} + +int knet_handle_get_transport_reconnect_interval(knet_handle_t knet_h, uint32_t *msecs) +{ + int savederrno = 0; + + if (!knet_h) { + errno = EINVAL; + return -1; + } + + if (!msecs) { + errno = EINVAL; + return -1; + } + + savederrno = pthread_rwlock_rdlock(&knet_h->global_rwlock); + if (savederrno) { + log_err(knet_h, KNET_SUB_HANDLE, "Unable to get read lock: %s", + strerror(savederrno)); + errno = savederrno; + return -1; + } + + *msecs = knet_h->reconnect_int; + + pthread_rwlock_unlock(&knet_h->global_rwlock); + return 0; +} diff --git a/libknet/transports.h b/libknet/transports.h index a5158fdd..448bf605 100644 --- a/libknet/transports.h +++ b/libknet/transports.h @@ -1,28 +1,22 @@ /* * Copyright (C) 2016-2017 Red Hat, Inc. All rights reserved. * * Authors: Fabio M. Di Nitto * * This software licensed under GPL-2.0+, LGPL-2.0+ */ #ifndef __KNET_TRANSPORTS_H__ #define __KNET_TRANSPORTS_H__ -knet_transport_ops_t *get_udp_transport(void); -knet_transport_ops_t *get_sctp_transport(void); -knet_transport_ops_t *get_loopback_transport(void); +int start_all_transports(knet_handle_t knet_h); +void stop_all_transports(knet_handle_t knet_h); -int _configure_common_socket(knet_handle_t knet_h, int sock, uint64_t flags, const char *type); -int _configure_transport_socket(knet_handle_t knet_h, int sock, struct sockaddr_storage *address, uint64_t flags, const char *type); - -int _init_socketpair(knet_handle_t knet_h, int *sock); -void _close_socketpair(knet_handle_t knet_h, int *sock); - -int _set_fd_tracker(knet_handle_t knet_h, int sockfd, uint8_t transport, uint8_t data_type, void *data); -int _is_valid_fd(knet_handle_t knet_h, int sockfd); - -int _sendmmsg(int sockfd, struct knet_mmsghdr *msgvec, unsigned int vlen, unsigned int flags); -int _recvmmsg(int sockfd, struct knet_mmsghdr *msgvec, unsigned int vlen, unsigned int flags); +int transport_link_set_config(knet_handle_t knet_h, struct knet_link *kn_link, uint8_t transport); +int transport_link_clear_config(knet_handle_t knet_h, struct knet_link *kn_link); +int transport_link_dyn_connect(knet_handle_t knet_h, int sockfd, struct knet_link *kn_link); +int transport_rx_sock_error(knet_handle_t knet_h, uint8_t transport, int sockfd, int recv_err, int recv_errno); +int transport_tx_sock_error(knet_handle_t knet_h, uint8_t transport, int sockfd, int recv_err, int recv_errno); +int transport_rx_is_data(knet_handle_t knet_h, uint8_t transport, int sockfd, struct knet_mmsghdr *msg); #endif