/* Copyright (c) 2013-2018 Dovecot authors, see the included COPYING file */ #include "lib.h" #include "net.h" #include "str.h" #include "hash.h" #include "llist.h" #include "array.h" #include "ioloop.h" #include "istream.h" #include "ostream.h" #include "connection.h" #include "dns-lookup.h" #include "iostream-rawlog.h" #include "iostream-ssl.h" #include "http-url.h" #include "http-client-private.h" /* Structure: http_client_context: Shared context between multiple independent HTTP clients. This allows host name lookup data, peer status and idle connections to be shared between clients. http_client: Acts much like a browser; it is not dedicated to a single host. Client can accept requests to different hosts, which can be served at different IPs. Redirects are handled in the background by making a new connection. Connections to new hosts are created once needed for servicing a request. http_client_request: The request semantics are similar to imapc commands. Create a request, optionally modify some aspects of it, and finally submit it. Once finished, a callback is called with the returned response. http_client_host_shared: We maintain a 'cache' of hosts for which we have looked up IPs. This cache is maintained in client context, so multiple clients can share it. One host can have multiple IPs. http_client_host: A host object maintains client-specific information for a host. The queues that the client has for this host are listed here. For one host, there is a separate queue for each used server port. http_client_queue: Requests are queued in a queue object. These queues are maintained for each host:port target and listed in the host object. The queue object is responsible for starting connection attempts to TCP port at the various IPs known for the host. http_client_peer_pool: A peer pool lists all unused and pending connections to a peer, grouped by a compatible configuration, e.g. in terms of SSL and rawlog. Once needed, peers can claim/request an existing/new connection from the pool. http_client_peer_shared: The shared peer object records state information about a peer, which is a service access point (ip:port or unix socket path). The peer object also maintains lists of idle and pending connections to this service, which are grouped in pools with compatible client configuration. Each client has a separate (non-shared) peer object for client-specific state information. http_client_peer: A peer object maintains client-specific information for a peer. Claimed connections are dedicated to one peer (and therefore one client). http-client-connection: This is an actual connection to a server. Once a connection is ready to handle requests, it claims a request from a queue object. One connection can service multiple hosts and one host can have multiple associated connections, possibly to different ips and ports. */ static struct event_category event_category_http_client = { .name = "http-client" }; static struct http_client_context *http_client_global_context = NULL; static void http_client_context_add_client(struct http_client_context *cctx, struct http_client *client); static void http_client_context_remove_client(struct http_client_context *cctx, struct http_client *client); /* * Client */ struct http_client * http_client_init_shared(struct http_client_context *cctx, const struct http_client_settings *set) { static unsigned int id = 0; struct http_client *client; const char *log_prefix; pool_t pool; size_t pool_size; pool_size = (set != NULL && set->ssl != NULL) ? 8192 : 1024; /* certs will be >4K */ pool = pool_alloconly_create("http client", pool_size); client = p_new(pool, struct http_client, 1); client->pool = pool; client->ioloop = current_ioloop; /* create private context if none is provided */ id++; if (cctx != NULL) { client->cctx = cctx; http_client_context_ref(cctx); log_prefix = t_strdup_printf("http-client[%u]: ", id); } else { i_assert(set != NULL); client->cctx = cctx = http_client_context_create(set); log_prefix = "http-client: "; } struct event *parent_event; if (set != NULL && set->event_parent != NULL) parent_event = set->event_parent; else if (cctx->event == NULL) parent_event = NULL; else { /* FIXME: we could use cctx->event, but it already has a log prefix that we don't want.. should we update event API to support replacing parent's log prefix? */ parent_event = event_get_parent(cctx->event); } client->event = event_create(parent_event); event_add_category(client->event, &event_category_http_client); event_set_forced_debug(client->event, (set != NULL && set->debug) || (cctx != NULL && cctx->set.debug)); event_set_append_log_prefix(client->event, log_prefix); /* merge provided settings with context defaults */ client->set = cctx->set; if (set != NULL) { client->set.dns_client = set->dns_client; client->set.dns_client_socket_path = p_strdup_empty(pool, set->dns_client_socket_path); client->set.dns_ttl_msecs = set->dns_ttl_msecs; if (set->user_agent != NULL && *set->user_agent != '\0') client->set.user_agent = p_strdup_empty(pool, set->user_agent); if (set->rawlog_dir != NULL && *set->rawlog_dir != '\0') client->set.rawlog_dir = p_strdup_empty(pool, set->rawlog_dir); if (set->ssl != NULL) client->set.ssl = ssl_iostream_settings_dup(pool, set->ssl); if (set->proxy_socket_path != NULL && *set->proxy_socket_path != '\0') { client->set.proxy_socket_path = p_strdup(pool, set->proxy_socket_path); client->set.proxy_url = NULL; } else if (set->proxy_url != NULL) { client->set.proxy_url = http_url_clone(pool, set->proxy_url); client->set.proxy_socket_path = NULL; } if (set->proxy_username != NULL && *set->proxy_username != '\0') { client->set.proxy_username = p_strdup_empty(pool, set->proxy_username); client->set.proxy_password = p_strdup(pool, set->proxy_password); } else if (set->proxy_url != NULL && set->proxy_url->user != NULL && *set->proxy_url->user != '\0') { client->set.proxy_username = p_strdup_empty(pool, set->proxy_url->user); client->set.proxy_password = p_strdup(pool, set->proxy_url->password); } if (set->max_idle_time_msecs > 0) client->set.max_idle_time_msecs = set->max_idle_time_msecs; if (set->max_parallel_connections > 0) client->set.max_parallel_connections = set->max_parallel_connections; if (set->max_pipelined_requests > 0) client->set.max_pipelined_requests = set->max_pipelined_requests; if (set->max_attempts > 0) client->set.max_attempts = set->max_attempts; if (set->max_connect_attempts > 0) client->set.max_connect_attempts = set->max_connect_attempts; if (set->connect_backoff_time_msecs > 0) { client->set.connect_backoff_time_msecs = set->connect_backoff_time_msecs; } if (set->connect_backoff_max_time_msecs > 0) { client->set.connect_backoff_max_time_msecs = set->connect_backoff_max_time_msecs; } client->set.no_auto_redirect = client->set.no_auto_redirect || set->no_auto_redirect; client->set.no_auto_retry = client->set.no_auto_retry || set->no_auto_retry; client->set.no_ssl_tunnel = client->set.no_ssl_tunnel || set->no_ssl_tunnel; if (set->max_redirects > 0) client->set.max_redirects = set->max_redirects; if (set->request_absolute_timeout_msecs > 0) { client->set.request_absolute_timeout_msecs = set->request_absolute_timeout_msecs; } if (set->request_timeout_msecs > 0) client->set.request_timeout_msecs = set->request_timeout_msecs; if (set->connect_timeout_msecs > 0) client->set.connect_timeout_msecs = set->connect_timeout_msecs; if (set->soft_connect_timeout_msecs > 0) client->set.soft_connect_timeout_msecs = set->soft_connect_timeout_msecs; if (set->socket_send_buffer_size > 0) client->set.socket_send_buffer_size = set->socket_send_buffer_size; if (set->socket_recv_buffer_size > 0) client->set.socket_recv_buffer_size = set->socket_recv_buffer_size; if (set->max_auto_retry_delay_secs > 0) client->set.max_auto_retry_delay_secs = set->max_auto_retry_delay_secs; client->set.debug = client->set.debug || set->debug; } i_array_init(&client->delayed_failing_requests, 1); http_client_context_add_client(cctx, client); return client; } struct http_client * http_client_init(const struct http_client_settings *set) { return http_client_init_shared(http_client_get_global_context(), set); } struct http_client * http_client_init_private(const struct http_client_settings *set) { return http_client_init_shared(NULL, set); } void http_client_deinit(struct http_client **_client) { struct http_client *client = *_client; struct http_client_request *req; struct http_client_host *host; struct http_client_peer *peer; *_client = NULL; /* destroy requests without calling callbacks */ req = client->requests_list; while (req != NULL) { struct http_client_request *next_req = req->next; http_client_request_destroy(&req); req = next_req; } i_assert(client->requests_count == 0); /* free peers */ while (client->peers_list != NULL) { peer = client->peers_list; http_client_peer_close(&peer); } /* free hosts */ while (client->hosts_list != NULL) { host = client->hosts_list; http_client_host_free(&host); } array_free(&client->delayed_failing_requests); timeout_remove(&client->to_failing_requests); if (client->ssl_ctx != NULL) ssl_iostream_context_unref(&client->ssl_ctx); http_client_context_remove_client(client->cctx, client); http_client_context_unref(&client->cctx); event_unref(&client->event); pool_unref(&client->pool); } static void http_client_do_switch_ioloop(struct http_client *client) { struct http_client_peer *peer; struct http_client_host *host; /* move peers */ for (peer = client->peers_list; peer != NULL; peer = peer->client_next) http_client_peer_switch_ioloop(peer); /* move hosts/queues */ for (host = client->hosts_list; host != NULL; host = host->client_next) http_client_host_switch_ioloop(host); /* move timeouts */ if (client->to_failing_requests != NULL) { client->to_failing_requests = io_loop_move_timeout(&client->to_failing_requests); } } struct ioloop *http_client_switch_ioloop(struct http_client *client) { struct ioloop *prev_ioloop = client->ioloop; client->ioloop = current_ioloop; http_client_do_switch_ioloop(client); http_client_context_switch_ioloop(client->cctx); return prev_ioloop; } void http_client_wait(struct http_client *client) { struct ioloop *prev_ioloop, *client_ioloop, *prev_client_ioloop; if (client->requests_count == 0) return; prev_ioloop = current_ioloop; client_ioloop = io_loop_create(); prev_client_ioloop = http_client_switch_ioloop(client); if (client->set.dns_client != NULL) dns_client_switch_ioloop(client->set.dns_client); /* either we're waiting for network I/O or we're getting out of a callback using timeout_add_short(0) */ i_assert(io_loop_have_ios(client_ioloop) || io_loop_have_immediate_timeouts(client_ioloop)); client->waiting = TRUE; do { e_debug(client->event, "Waiting for %d requests to finish", client->requests_count); io_loop_run(client_ioloop); } while (client->requests_count > 0); client->waiting = FALSE; e_debug(client->event, "All requests finished"); if (prev_client_ioloop != NULL) io_loop_set_current(prev_client_ioloop); else io_loop_set_current(prev_ioloop); (void)http_client_switch_ioloop(client); if (client->set.dns_client != NULL) dns_client_switch_ioloop(client->set.dns_client); io_loop_set_current(client_ioloop); io_loop_destroy(&client_ioloop); } unsigned int http_client_get_pending_request_count(struct http_client *client) { return client->requests_count; } int http_client_init_ssl_ctx(struct http_client *client, const char **error_r) { const char *error; if (client->ssl_ctx != NULL) return 0; if (client->set.ssl == NULL) { *error_r = "Requested https connection, but no SSL settings given"; return -1; } if (ssl_iostream_client_context_cache_get(client->set.ssl, &client->ssl_ctx, &error) < 0) { *error_r = t_strdup_printf("Couldn't initialize SSL context: %s", error); return -1; } return 0; } /* * Delayed request errors */ static void http_client_handle_request_errors(struct http_client *client) { struct http_client_request *req; timeout_remove(&client->to_failing_requests); array_foreach_elem(&client->delayed_failing_requests, req) { i_assert(req->refcount == 1); http_client_request_error_delayed(&req); } array_clear(&client->delayed_failing_requests); } void http_client_delay_request_error(struct http_client *client, struct http_client_request *req) { if (client->to_failing_requests == NULL) { client->to_failing_requests = timeout_add_short_to(client->ioloop, 0, http_client_handle_request_errors, client); } array_push_back(&client->delayed_failing_requests, &req); } void http_client_remove_request_error(struct http_client *client, struct http_client_request *req) { struct http_client_request *const *reqs; unsigned int i, count; reqs = array_get(&client->delayed_failing_requests, &count); for (i = 0; i < count; i++) { if (reqs[i] == req) { array_delete(&client->delayed_failing_requests, i, 1); return; } } } /* * Client shared context */ struct http_client_context * http_client_context_create(const struct http_client_settings *set) { struct http_client_context *cctx; pool_t pool; size_t pool_size; pool_size = (set->ssl != NULL) ? 8192 : 1024; /* certs will be >4K */ pool = pool_alloconly_create("http client context", pool_size); cctx = p_new(pool, struct http_client_context, 1); cctx->pool = pool; cctx->refcount = 1; cctx->ioloop = current_ioloop; cctx->event = event_create(set->event_parent); event_add_category(cctx->event, &event_category_http_client); event_set_forced_debug(cctx->event, set->debug); event_set_append_log_prefix(cctx->event, "http-client: "); cctx->set.dns_client = set->dns_client; cctx->set.dns_client_socket_path = p_strdup_empty(pool, set->dns_client_socket_path); cctx->set.dns_ttl_msecs = (set->dns_ttl_msecs == 0 ? HTTP_CLIENT_DEFAULT_DNS_TTL_MSECS : set->dns_ttl_msecs); cctx->set.user_agent = p_strdup_empty(pool, set->user_agent); cctx->set.rawlog_dir = p_strdup_empty(pool, set->rawlog_dir); if (set->ssl != NULL) cctx->set.ssl = ssl_iostream_settings_dup(pool, set->ssl); if (set->proxy_socket_path != NULL && *set->proxy_socket_path != '\0') { cctx->set.proxy_socket_path = p_strdup(pool, set->proxy_socket_path); } else if (set->proxy_url != NULL) { cctx->set.proxy_url = http_url_clone(pool, set->proxy_url); } if (set->proxy_username != NULL && *set->proxy_username != '\0') { cctx->set.proxy_username = p_strdup_empty(pool, set->proxy_username); cctx->set.proxy_password = p_strdup(pool, set->proxy_password); } else if (set->proxy_url != NULL) { cctx->set.proxy_username = p_strdup_empty(pool, set->proxy_url->user); cctx->set.proxy_password = p_strdup(pool, set->proxy_url->password); } cctx->set.max_idle_time_msecs = set->max_idle_time_msecs; cctx->set.max_pipelined_requests = (set->max_pipelined_requests > 0 ? set->max_pipelined_requests : 1); cctx->set.max_parallel_connections = (set->max_parallel_connections > 0 ? set->max_parallel_connections : 1); cctx->set.max_attempts = set->max_attempts; cctx->set.max_connect_attempts = set->max_connect_attempts; cctx->set.connect_backoff_time_msecs = set->connect_backoff_time_msecs == 0 ? HTTP_CLIENT_DEFAULT_BACKOFF_TIME_MSECS : set->connect_backoff_time_msecs; cctx->set.connect_backoff_max_time_msecs = set->connect_backoff_max_time_msecs == 0 ? HTTP_CLIENT_DEFAULT_BACKOFF_MAX_TIME_MSECS : set->connect_backoff_max_time_msecs; cctx->set.no_auto_redirect = set->no_auto_redirect; cctx->set.no_auto_retry = set->no_auto_retry; cctx->set.no_ssl_tunnel = set->no_ssl_tunnel; cctx->set.max_redirects = set->max_redirects; cctx->set.response_hdr_limits = set->response_hdr_limits; cctx->set.request_absolute_timeout_msecs = set->request_absolute_timeout_msecs; cctx->set.request_timeout_msecs = set->request_timeout_msecs == 0 ? HTTP_CLIENT_DEFAULT_REQUEST_TIMEOUT_MSECS : set->request_timeout_msecs; cctx->set.connect_timeout_msecs = set->connect_timeout_msecs; cctx->set.soft_connect_timeout_msecs = set->soft_connect_timeout_msecs; cctx->set.max_auto_retry_delay_secs = set->max_auto_retry_delay_secs; cctx->set.socket_send_buffer_size = set->socket_send_buffer_size; cctx->set.socket_recv_buffer_size = set->socket_recv_buffer_size; cctx->set.debug = set->debug; cctx->conn_list = http_client_connection_list_init(); hash_table_create(&cctx->hosts, default_pool, 0, str_hash, strcmp); hash_table_create(&cctx->peers, default_pool, 0, http_client_peer_addr_hash, http_client_peer_addr_cmp); return cctx; } void http_client_context_ref(struct http_client_context *cctx) { cctx->refcount++; } void http_client_context_unref(struct http_client_context **_cctx) { struct http_client_context *cctx = *_cctx; struct http_client_peer_shared *peer; struct http_client_host_shared *hshared; *_cctx = NULL; i_assert(cctx->refcount > 0); if (--cctx->refcount > 0) return; /* free hosts */ while (cctx->hosts_list != NULL) { hshared = cctx->hosts_list; http_client_host_shared_free(&hshared); } hash_table_destroy(&cctx->hosts); /* close all idle connections */ while (cctx->peers_list != NULL) { peer = cctx->peers_list; http_client_peer_shared_close(&peer); i_assert(peer == NULL); } hash_table_destroy(&cctx->peers); connection_list_deinit(&cctx->conn_list); event_unref(&cctx->event); pool_unref(&cctx->pool); } static unsigned int http_client_get_dns_lookup_timeout_msecs(const struct http_client_settings *set) { if (set->connect_timeout_msecs > 0) return set->connect_timeout_msecs; if (set->request_timeout_msecs > 0) return set->request_timeout_msecs; return HTTP_CLIENT_DEFAULT_DNS_LOOKUP_TIMEOUT_MSECS; } static void http_client_context_update_settings(struct http_client_context *cctx) { struct http_client *client; bool debug; /* revert back to context settings */ cctx->dns_client = cctx->set.dns_client; cctx->dns_client_socket_path = cctx->set.dns_client_socket_path; cctx->dns_ttl_msecs = cctx->set.dns_ttl_msecs; cctx->dns_lookup_timeout_msecs = http_client_get_dns_lookup_timeout_msecs(&cctx->set); debug = cctx->set.debug; i_assert(cctx->dns_ttl_msecs > 0); i_assert(cctx->dns_lookup_timeout_msecs > 0); /* override with available client settings */ for (client = cctx->clients_list; client != NULL; client = client->next) { unsigned dns_lookup_timeout_msecs = http_client_get_dns_lookup_timeout_msecs(&client->set); if (cctx->dns_client == NULL) cctx->dns_client = client->set.dns_client; if (cctx->dns_client_socket_path == NULL) { cctx->dns_client_socket_path = client->set.dns_client_socket_path; } if (client->set.dns_ttl_msecs != 0 && cctx->dns_ttl_msecs > client->set.dns_ttl_msecs) cctx->dns_ttl_msecs = client->set.dns_ttl_msecs; if (dns_lookup_timeout_msecs != 0 && cctx->dns_lookup_timeout_msecs > dns_lookup_timeout_msecs) { cctx->dns_lookup_timeout_msecs = dns_lookup_timeout_msecs; } debug = debug || client->set.debug; } event_set_forced_debug(cctx->event, debug); } static void http_client_context_add_client(struct http_client_context *cctx, struct http_client *client) { DLLIST_PREPEND(&cctx->clients_list, client); http_client_context_update_settings(cctx); } static void http_client_context_remove_client(struct http_client_context *cctx, struct http_client *client) { DLLIST_REMOVE(&cctx->clients_list, client); http_client_context_update_settings(cctx); if (cctx->ioloop != current_ioloop && cctx->ioloop == client->ioloop && cctx->clients_list != NULL) { struct ioloop *prev_ioloop = current_ioloop; io_loop_set_current(cctx->clients_list->ioloop); http_client_context_switch_ioloop(cctx); io_loop_set_current(prev_ioloop); } } static void http_client_context_close(struct http_client_context *cctx) { struct connection *_conn, *_conn_next; struct http_client_host_shared *hshared; struct http_client_peer_shared *pshared; /* Switching to NULL ioloop; close all hosts, peers, and connections */ i_assert(cctx->clients_list == NULL); _conn = cctx->conn_list->connections; while (_conn != NULL) { struct http_client_connection *conn = (struct http_client_connection *)_conn; _conn_next = _conn->next; http_client_connection_close(&conn); _conn = _conn_next; } while (cctx->hosts_list != NULL) { hshared = cctx->hosts_list; http_client_host_shared_free(&hshared); } while (cctx->peers_list != NULL) { pshared = cctx->peers_list; http_client_peer_shared_close(&pshared); } } static void http_client_context_do_switch_ioloop(struct http_client_context *cctx) { struct connection *_conn = cctx->conn_list->connections; struct http_client_host_shared *hshared; struct http_client_peer_shared *pshared; /* move connections */ /* FIXME: we wouldn't necessarily need to switch all of them immediately, only those that have requests now. but also connections that get new requests before ioloop is switched again.. */ for (; _conn != NULL; _conn = _conn->next) { struct http_client_connection *conn = (struct http_client_connection *)_conn; http_client_connection_switch_ioloop(conn); } /* move backoff timeouts */ for (pshared = cctx->peers_list; pshared != NULL; pshared = pshared->next) http_client_peer_shared_switch_ioloop(pshared); /* move dns lookups and delayed requests */ for (hshared = cctx->hosts_list; hshared != NULL; hshared = hshared->next) http_client_host_shared_switch_ioloop(hshared); } void http_client_context_switch_ioloop(struct http_client_context *cctx) { cctx->ioloop = current_ioloop; http_client_context_do_switch_ioloop(cctx); } static void http_client_global_context_ioloop_switched( struct ioloop *prev_ioloop ATTR_UNUSED) { struct http_client_context *cctx = http_client_global_context; i_assert(cctx != NULL); if (current_ioloop == NULL) { http_client_context_close(cctx); return; } if (cctx->clients_list == NULL) { /* follow the current ioloop if there is no client */ http_client_context_switch_ioloop(cctx); } } static void http_client_global_context_free(void) { /* drop ioloop switch callback to make absolutely sure there is no recursion. */ io_loop_remove_switch_callback(http_client_global_context_ioloop_switched); http_client_context_unref(&http_client_global_context); } struct http_client_context *http_client_get_global_context(void) { if (http_client_global_context != NULL) return http_client_global_context; struct http_client_settings set; i_zero(&set); http_client_global_context = http_client_context_create(&set); /* keep this a bit higher than lib-ssl-iostream */ lib_atexit_priority(http_client_global_context_free, LIB_ATEXIT_PRIORITY_LOW-1); io_loop_add_switch_callback(http_client_global_context_ioloop_switched); return http_client_global_context; }