/* Copyright (C) CZ.NIC, z.s.p.o. * SPDX-License-Identifier: GPL-3.0-or-later */ #include #include "lib/defines.h" #include "daemon/session.h" #include "daemon/tls.h" #include "daemon/http.h" #include "daemon/worker.h" #include "daemon/io.h" #include "daemon/proxyv2.h" #include "lib/generic/queue.h" #define TLS_CHUNK_SIZE (16 * 1024) /* Initial max frame size: https://tools.ietf.org/html/rfc7540#section-6.5.2 */ #define HTTP_MAX_FRAME_SIZE 16384 /* Per-socket (TCP or UDP) persistent structure. * * In particular note that for UDP clients it's just one session (per socket) * shared for all clients. For TCP/TLS it's also for the connection-specific socket, * i.e one session per connection. * * LATER(optim.): the memory here is used a bit wastefully. */ struct session { struct session_flags sflags; /**< miscellaneous flags. */ union kr_sockaddr peer; /**< address of peer; not for UDP clients (downstream) */ union kr_sockaddr sockname; /**< our local address; for UDP it may be a wildcard */ uv_handle_t *handle; /**< libuv handle for IO operations. */ uv_timer_t timeout; /**< libuv handle for timer. */ struct tls_ctx *tls_ctx; /**< server side tls-related data. */ struct tls_client_ctx *tls_client_ctx; /**< client side tls-related data. */ struct proxy_result *proxy; /**< PROXYv2 data for TCP. May be `NULL` if not proxied. */ #if ENABLE_DOH2 struct http_ctx *http_ctx; /**< server side http-related data. */ #endif trie_t *tasks; /**< list of tasks associated with given session. */ queue_t(struct qr_task *) waiting; /**< list of tasks waiting for sending to upstream. */ uint8_t *wire_buf; /**< Buffer for DNS message, except for XDP. */ ssize_t wire_buf_size; /**< Buffer size. */ ssize_t wire_buf_start_idx; /**< Data start offset in wire_buf. */ ssize_t wire_buf_end_idx; /**< Data end offset in wire_buf. */ uint64_t last_activity; /**< Time of last IO activity (if any occurs). * Otherwise session creation time. */ bool was_useful; /**< I.e. produced a DNS message at some point. */ }; static void on_session_close(uv_handle_t *handle) { struct session *session = handle->data; kr_require(session->handle == handle); io_free(handle); } static void on_session_timer_close(uv_handle_t *timer) { struct session *session = timer->data; uv_handle_t *handle = session->handle; kr_require(handle && handle->data == session); kr_require(session->sflags.outgoing || handle->type == UV_TCP); if (!uv_is_closing(handle)) { uv_close(handle, on_session_close); } } void session_free(struct session *session) { if (session) { session_clear(session); free(session); } } void session_clear(struct session *session) { kr_require(session_is_empty(session)); if (session->handle && session->handle->type == UV_TCP) { free(session->wire_buf); } free(session->proxy); #if ENABLE_DOH2 http_free(session->http_ctx); #endif trie_clear(session->tasks); trie_free(session->tasks); queue_deinit(session->waiting); tls_free(session->tls_ctx); tls_client_ctx_free(session->tls_client_ctx); memset(session, 0, sizeof(*session)); } void session_close(struct session *session) { kr_require(session_is_empty(session)); if (session->sflags.closing) { return; } uv_handle_t *handle = session->handle; io_stop_read(handle); session->sflags.closing = true; if (!uv_is_closing((uv_handle_t *)&session->timeout)) { uv_timer_stop(&session->timeout); if (session->tls_client_ctx) { tls_client_close(session->tls_client_ctx); } if (session->tls_ctx) { tls_close(&session->tls_ctx->c); } session->timeout.data = session; uv_close((uv_handle_t *)&session->timeout, on_session_timer_close); } } bool session_was_useful(const struct session *session) { return session->was_useful; } int session_start_read(struct session *session) { return io_start_read(session->handle); } int session_stop_read(struct session *session) { return io_stop_read(session->handle); } int session_waitinglist_push(struct session *session, struct qr_task *task) { queue_push(session->waiting, task); worker_task_ref(task); return kr_ok(); } struct qr_task *session_waitinglist_get(const struct session *session) { return (queue_len(session->waiting) > 0) ? (queue_head(session->waiting)) : NULL; } struct qr_task *session_waitinglist_pop(struct session *session, bool deref) { struct qr_task *t = session_waitinglist_get(session); queue_pop(session->waiting); if (deref) { worker_task_unref(t); } return t; } int session_tasklist_add(struct session *session, struct qr_task *task) { trie_t *t = session->tasks; uint16_t task_msg_id = 0; const char *key = NULL; size_t key_len = 0; if (session->sflags.outgoing) { knot_pkt_t *pktbuf = worker_task_get_pktbuf(task); task_msg_id = knot_wire_get_id(pktbuf->wire); key = (const char *)&task_msg_id; key_len = sizeof(task_msg_id); } else { key = (const char *)&task; key_len = sizeof(char *); } trie_val_t *v = trie_get_ins(t, key, key_len); if (kr_fails_assert(v)) return kr_error(ENOMEM); if (*v == NULL) { *v = task; worker_task_ref(task); } else if (kr_fails_assert(*v == task)) { return kr_error(EINVAL); } return kr_ok(); } int session_tasklist_del(struct session *session, struct qr_task *task) { trie_t *t = session->tasks; uint16_t task_msg_id = 0; const char *key = NULL; size_t key_len = 0; trie_val_t val; if (session->sflags.outgoing) { knot_pkt_t *pktbuf = worker_task_get_pktbuf(task); task_msg_id = knot_wire_get_id(pktbuf->wire); key = (const char *)&task_msg_id; key_len = sizeof(task_msg_id); } else { key = (const char *)&task; key_len = sizeof(char *); } int ret = trie_del(t, key, key_len, &val); if (ret == KNOT_EOK) { kr_require(val == task); worker_task_unref(val); } return ret; } struct qr_task *session_tasklist_get_first(struct session *session) { trie_val_t *val = trie_get_first(session->tasks, NULL, NULL); return val ? (struct qr_task *) *val : NULL; } struct qr_task *session_tasklist_del_first(struct session *session, bool deref) { trie_val_t val = NULL; int res = trie_del_first(session->tasks, NULL, NULL, &val); if (res != KNOT_EOK) { val = NULL; } else if (deref) { worker_task_unref(val); } return (struct qr_task *)val; } struct qr_task* session_tasklist_del_msgid(const struct session *session, uint16_t msg_id) { if (kr_fails_assert(session->sflags.outgoing)) return NULL; trie_t *t = session->tasks; struct qr_task *ret = NULL; const char *key = (const char *)&msg_id; size_t key_len = sizeof(msg_id); trie_val_t val; int res = trie_del(t, key, key_len, &val); if (res == KNOT_EOK) { if (worker_task_numrefs(val) > 1) { ret = val; } worker_task_unref(val); } return ret; } struct qr_task* session_tasklist_find_msgid(const struct session *session, uint16_t msg_id) { if (kr_fails_assert(session->sflags.outgoing)) return NULL; trie_t *t = session->tasks; struct qr_task *ret = NULL; trie_val_t *val = trie_get_try(t, (char *)&msg_id, sizeof(msg_id)); if (val) { ret = *val; } return ret; } struct session_flags *session_flags(struct session *session) { return &session->sflags; } struct sockaddr *session_get_peer(struct session *session) { return &session->peer.ip; } struct sockaddr *session_get_sockname(struct session *session) { return &session->sockname.ip; } struct tls_ctx *session_tls_get_server_ctx(const struct session *session) { return session->tls_ctx; } void session_tls_set_server_ctx(struct session *session, struct tls_ctx *ctx) { session->tls_ctx = ctx; } struct tls_client_ctx *session_tls_get_client_ctx(const struct session *session) { return session->tls_client_ctx; } void session_tls_set_client_ctx(struct session *session, struct tls_client_ctx *ctx) { session->tls_client_ctx = ctx; } struct tls_common_ctx *session_tls_get_common_ctx(const struct session *session) { struct tls_common_ctx *tls_ctx = session->sflags.outgoing ? &session->tls_client_ctx->c : &session->tls_ctx->c; return tls_ctx; } #if ENABLE_DOH2 struct http_ctx *session_http_get_server_ctx(const struct session *session) { return session->http_ctx; } void session_http_set_server_ctx(struct session *session, struct http_ctx *ctx) { session->http_ctx = ctx; } #endif uv_handle_t *session_get_handle(struct session *session) { return session->handle; } struct session *session_get(uv_handle_t *h) { return h->data; } struct session *session_new(uv_handle_t *handle, bool has_tls, bool has_http) { if (!handle) { return NULL; } struct session *session = calloc(1, sizeof(struct session)); if (!session) { return NULL; } queue_init(session->waiting); session->tasks = trie_create(NULL); if (handle->type == UV_TCP) { size_t wire_buffer_size = KNOT_WIRE_MAX_PKTSIZE; if (has_tls) { /* When decoding large packets, * gnutls gives the application chunks of size 16 kb each. */ wire_buffer_size += TLS_CHUNK_SIZE; session->sflags.has_tls = true; } #if ENABLE_DOH2 if (has_http) { /* When decoding large packets, * HTTP/2 frames can be up to 16 KB by default. */ wire_buffer_size += HTTP_MAX_FRAME_SIZE; session->sflags.has_http = true; } #endif uint8_t *wire_buf = malloc(wire_buffer_size); if (!wire_buf) { free(session); return NULL; } session->wire_buf = wire_buf; session->wire_buf_size = wire_buffer_size; } else if (handle->type == UV_UDP) { /* We use the singleton buffer from worker for all UDP (!) * libuv documentation doesn't really guarantee this is OK, * but the implementation for unix systems does not hold * the buffer (both UDP and TCP) - always makes a NON-blocking * syscall that fills the buffer and immediately calls * the callback, whatever the result of the operation. * We still need to keep in mind to only touch the buffer * in this callback... */ kr_require(the_worker); session->wire_buf = the_worker->wire_buf; session->wire_buf_size = sizeof(the_worker->wire_buf); } else { kr_assert(handle->type == UV_POLL/*XDP*/); /* - wire_buf* are left zeroed, as they make no sense * - timer is unused but OK for simplicity (server-side sessions are few) */ } uv_timer_init(handle->loop, &session->timeout); session->handle = handle; handle->data = session; session->timeout.data = session; session_touch(session); return session; } size_t session_tasklist_get_len(const struct session *session) { return trie_weight(session->tasks); } size_t session_waitinglist_get_len(const struct session *session) { return queue_len(session->waiting); } bool session_tasklist_is_empty(const struct session *session) { return session_tasklist_get_len(session) == 0; } bool session_waitinglist_is_empty(const struct session *session) { return session_waitinglist_get_len(session) == 0; } bool session_is_empty(const struct session *session) { return session_tasklist_is_empty(session) && session_waitinglist_is_empty(session); } bool session_has_tls(const struct session *session) { return session->sflags.has_tls; } void session_set_has_tls(struct session *session, bool has_tls) { session->sflags.has_tls = has_tls; } void session_waitinglist_retry(struct session *session, bool increase_timeout_cnt) { while (!session_waitinglist_is_empty(session)) { struct qr_task *task = session_waitinglist_pop(session, false); if (increase_timeout_cnt) { worker_task_timeout_inc(task); } worker_task_step(task, &session->peer.ip, NULL); worker_task_unref(task); } } void session_waitinglist_finalize(struct session *session, int status) { while (!session_waitinglist_is_empty(session)) { struct qr_task *t = session_waitinglist_pop(session, false); worker_task_finalize(t, status); worker_task_unref(t); } } struct proxy_result *session_proxy_create(struct session *session) { if (!kr_fails_assert(!session->proxy)) { session->proxy = calloc(1, sizeof(struct proxy_result)); kr_require(session->proxy); } return session->proxy; } struct proxy_result *session_proxy_get(struct session *session) { return session->proxy; } void session_tasklist_finalize(struct session *session, int status) { while (session_tasklist_get_len(session) > 0) { struct qr_task *t = session_tasklist_del_first(session, false); kr_require(worker_task_numrefs(t) > 0); worker_task_finalize(t, status); worker_task_unref(t); } } int session_tasklist_finalize_expired(struct session *session) { int ret = 0; queue_t(struct qr_task *) q; uint64_t now = kr_now(); trie_t *t = session->tasks; trie_it_t *it; queue_init(q); for (it = trie_it_begin(t); !trie_it_finished(it); trie_it_next(it)) { trie_val_t *v = trie_it_val(it); struct qr_task *task = (struct qr_task *)*v; if ((now - worker_task_creation_time(task)) >= KR_RESOLVE_TIME_LIMIT) { struct kr_request *req = worker_task_request(task); if (!kr_fails_assert(req)) kr_query_inform_timeout(req, req->current_query); queue_push(q, task); worker_task_ref(task); } } trie_it_free(it); struct qr_task *task = NULL; uint16_t msg_id = 0; char *key = (char *)&task; int32_t keylen = sizeof(struct qr_task *); if (session->sflags.outgoing) { key = (char *)&msg_id; keylen = sizeof(msg_id); } while (queue_len(q) > 0) { task = queue_head(q); if (session->sflags.outgoing) { knot_pkt_t *pktbuf = worker_task_get_pktbuf(task); msg_id = knot_wire_get_id(pktbuf->wire); } int res = trie_del(t, key, keylen, NULL); if (!worker_task_finished(task)) { /* task->pending_count must be zero, * but there are can be followers, * so run worker_task_subreq_finalize() to ensure retrying * for all the followers. */ worker_task_subreq_finalize(task); worker_task_finalize(task, KR_STATE_FAIL); } if (res == KNOT_EOK) { worker_task_unref(task); } queue_pop(q); worker_task_unref(task); ++ret; } queue_deinit(q); return ret; } int session_timer_start(struct session *session, uv_timer_cb cb, uint64_t timeout, uint64_t repeat) { uv_timer_t *timer = &session->timeout; // Session might be closing and get here e.g. through a late on_send callback. const bool is_closing = uv_is_closing((uv_handle_t *)timer); if (is_closing || kr_fails_assert(is_closing == session->sflags.closing)) return kr_error(EINVAL); if (kr_fails_assert(timer->data == session)) return kr_error(EINVAL); int ret = uv_timer_start(timer, cb, timeout, repeat); if (ret != 0) { uv_timer_stop(timer); return kr_error(ret); } return kr_ok(); } int session_timer_restart(struct session *session) { kr_require(!uv_is_closing((uv_handle_t *)&session->timeout)); return uv_timer_again(&session->timeout); } int session_timer_stop(struct session *session) { return uv_timer_stop(&session->timeout); } ssize_t session_wirebuf_consume(struct session *session, const uint8_t *data, ssize_t len) { if (kr_fails_assert(data == &session->wire_buf[session->wire_buf_end_idx])) return kr_error(EINVAL); if (kr_fails_assert(len >= 0)) return kr_error(EINVAL); if (kr_fails_assert(session->wire_buf_end_idx + len <= session->wire_buf_size)) return kr_error(EINVAL); session->wire_buf_end_idx += len; return len; } ssize_t session_wirebuf_trim(struct session *session, ssize_t len) { if (kr_fails_assert(len >= 0)) return kr_error(EINVAL); if (kr_fails_assert(session->wire_buf_start_idx + len <= session->wire_buf_size)) return kr_error(EINVAL); session->wire_buf_start_idx += len; if (session->wire_buf_start_idx > session->wire_buf_end_idx) session->wire_buf_end_idx = session->wire_buf_start_idx; return len; } knot_pkt_t *session_produce_packet(struct session *session, knot_mm_t *mm) { session->sflags.wirebuf_error = false; if (session->wire_buf_end_idx == 0) { return NULL; } if (session->wire_buf_start_idx == session->wire_buf_end_idx) { session->wire_buf_start_idx = 0; session->wire_buf_end_idx = 0; return NULL; } if (session->wire_buf_start_idx > session->wire_buf_end_idx) { session->sflags.wirebuf_error = true; session->wire_buf_start_idx = 0; session->wire_buf_end_idx = 0; return NULL; } const uv_handle_t *handle = session->handle; uint8_t *msg_start = &session->wire_buf[session->wire_buf_start_idx]; ssize_t wirebuf_msg_data_size = session->wire_buf_end_idx - session->wire_buf_start_idx; uint16_t msg_size = 0; if (!handle) { session->sflags.wirebuf_error = true; return NULL; } else if (handle->type == UV_TCP) { if (wirebuf_msg_data_size < 2) { return NULL; } msg_size = knot_wire_read_u16(msg_start); if (msg_size >= session->wire_buf_size) { session->sflags.wirebuf_error = true; return NULL; } if (msg_size + 2 > wirebuf_msg_data_size) { return NULL; } if (msg_size == 0) { session->sflags.wirebuf_error = true; return NULL; } msg_start += 2; } else if (wirebuf_msg_data_size < UINT16_MAX) { msg_size = wirebuf_msg_data_size; } else { session->sflags.wirebuf_error = true; return NULL; } session->was_useful = true; knot_pkt_t *pkt = knot_pkt_new(msg_start, msg_size, mm); session->sflags.wirebuf_error = (pkt == NULL); return pkt; } int session_discard_packet(struct session *session, const knot_pkt_t *pkt) { uv_handle_t *handle = session->handle; /* Pointer to data start in wire_buf */ uint8_t *wirebuf_data_start = &session->wire_buf[session->wire_buf_start_idx]; /* Number of data bytes in wire_buf */ size_t wirebuf_data_size = session->wire_buf_end_idx - session->wire_buf_start_idx; /* Pointer to message start in wire_buf */ uint8_t *wirebuf_msg_start = wirebuf_data_start; /* Number of message bytes in wire_buf. * For UDP it is the same number as wirebuf_data_size. */ size_t wirebuf_msg_size = wirebuf_data_size; /* Wire data from parsed packet. */ uint8_t *pkt_msg_start = pkt->wire; /* Number of bytes in packet wire buffer. */ size_t pkt_msg_size = pkt->size; if (knot_pkt_has_tsig(pkt)) { pkt_msg_size += pkt->tsig_wire.len; } session->sflags.wirebuf_error = true; if (!handle) { return kr_error(EINVAL); } else if (handle->type == UV_TCP) { /* wire_buf contains TCP DNS message. */ if (kr_fails_assert(wirebuf_data_size >= 2)) { /* TCP message length field isn't in buffer, must not happen. */ session->wire_buf_start_idx = 0; session->wire_buf_end_idx = 0; return kr_error(EINVAL); } wirebuf_msg_size = knot_wire_read_u16(wirebuf_msg_start); wirebuf_msg_start += 2; if (kr_fails_assert(wirebuf_msg_size + 2 <= wirebuf_data_size)) { /* TCP message length field is greater then * number of bytes in buffer, must not happen. */ session->wire_buf_start_idx = 0; session->wire_buf_end_idx = 0; return kr_error(EINVAL); } } if (kr_fails_assert(wirebuf_msg_start == pkt_msg_start)) { /* packet wirebuf must be located at the beginning * of the session wirebuf, must not happen. */ session->wire_buf_start_idx = 0; session->wire_buf_end_idx = 0; return kr_error(EINVAL); } if (kr_fails_assert(wirebuf_msg_size >= pkt_msg_size)) { /* Message length field is lesser then packet size, * must not happen. */ session->wire_buf_start_idx = 0; session->wire_buf_end_idx = 0; return kr_error(EINVAL); } if (handle->type == UV_TCP) { session->wire_buf_start_idx += wirebuf_msg_size + 2; } else { session->wire_buf_start_idx += pkt_msg_size; } session->sflags.wirebuf_error = false; wirebuf_data_size = session->wire_buf_end_idx - session->wire_buf_start_idx; if (wirebuf_data_size == 0) { session_wirebuf_discard(session); } else if (wirebuf_data_size < KNOT_WIRE_HEADER_SIZE) { session_wirebuf_compress(session); } return kr_ok(); } void session_wirebuf_discard(struct session *session) { session->wire_buf_start_idx = 0; session->wire_buf_end_idx = 0; } void session_wirebuf_compress(struct session *session) { if (session->wire_buf_start_idx == 0) { return; } uint8_t *wirebuf_data_start = &session->wire_buf[session->wire_buf_start_idx]; size_t wirebuf_data_size = session->wire_buf_end_idx - session->wire_buf_start_idx; if (session->wire_buf_start_idx < wirebuf_data_size) { memmove(session->wire_buf, wirebuf_data_start, wirebuf_data_size); } else { memcpy(session->wire_buf, wirebuf_data_start, wirebuf_data_size); } session->wire_buf_start_idx = 0; session->wire_buf_end_idx = wirebuf_data_size; } bool session_wirebuf_error(struct session *session) { return session->sflags.wirebuf_error; } uint8_t *session_wirebuf_get_start(struct session *session) { return session->wire_buf; } size_t session_wirebuf_get_size(struct session *session) { return session->wire_buf_size; } uint8_t *session_wirebuf_get_free_start(struct session *session) { return &session->wire_buf[session->wire_buf_end_idx]; } size_t session_wirebuf_get_free_size(struct session *session) { return session->wire_buf_size - session->wire_buf_end_idx; } void session_poison(struct session *session) { kr_asan_poison(session, sizeof(*session)); } void session_unpoison(struct session *session) { kr_asan_unpoison(session, sizeof(*session)); } int session_wirebuf_process(struct session *session, struct io_comm_data *comm) { int ret = 0; if (session->wire_buf_start_idx == session->wire_buf_end_idx) return ret; size_t wirebuf_data_size = session->wire_buf_end_idx - session->wire_buf_start_idx; uint32_t max_iterations = (wirebuf_data_size / (KNOT_WIRE_HEADER_SIZE + KNOT_WIRE_QUESTION_MIN_SIZE)) + 1; knot_pkt_t *pkt = NULL; while (((pkt = session_produce_packet(session, &the_worker->pkt_pool)) != NULL) && (ret < max_iterations)) { if (kr_fails_assert(!session_wirebuf_error(session))) return -1; int res = worker_submit(session, comm, NULL, NULL, pkt); /* Errors from worker_submit() are intentionally *not* handled in order to * ensure the entire wire buffer is processed. */ if (res == kr_ok()) ret += 1; if (session_discard_packet(session, pkt) < 0) { /* Packet data isn't stored in memory as expected. * something went wrong, normally should not happen. */ break; } } /* worker_submit() may cause the session to close (e.g. due to IO * write error when the packet triggers an immediate answer). This is * an error state, as well as any wirebuf error. */ if (session->sflags.closing || session_wirebuf_error(session)) ret = -1; return ret; } void session_kill_ioreq(struct session *session, struct qr_task *task) { if (!session || session->sflags.closing) return; if (kr_fails_assert(session->sflags.outgoing && session->handle)) return; session_tasklist_del(session, task); if (session->handle->type == UV_UDP) { session_close(session); return; } } /** Update timestamp */ void session_touch(struct session *session) { session->last_activity = kr_now(); } uint64_t session_last_activity(struct session *session) { return session->last_activity; }