/* This file is part of GNUnet. Copyright (C) 2009-2017 GNUnet e.V. GNUnet is free software: you can redistribute it and/or modify it under the terms of the GNU Affero General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. GNUnet is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Affero General Public License for more details. You should have received a copy of the GNU Affero General Public License along with this program. If not, see . SPDX-License-Identifier: AGPL3.0-or-later */ /** * @author Christian Grothoff * * @file include/gnunet_core_service.h * Core service; the main API for encrypted P2P communications * * @defgroup core Core service * Encrypted direct communication between peers * * @see [Documentation](https://gnunet.org/gnunet-core-subsystem) * * @{ */ #ifndef GNUNET_CORE_SERVICE_H #define GNUNET_CORE_SERVICE_H #ifdef __cplusplus extern "C" { #if 0 /* keep Emacsens' auto-indent happy */ } #endif #endif #include "gnunet_util_lib.h" #include "gnunet_transport_service.h" /** * Version number of GNUnet-core API. */ #define GNUNET_CORE_VERSION 0x00000001 /** * Traffic priorities. */ enum GNUNET_CORE_Priority { /** * Lowest priority, i.e. background traffic (i.e. fs) */ GNUNET_CORE_PRIO_BACKGROUND = 0, /** * Normal traffic (i.e. cadet/dv relay, DHT) */ GNUNET_CORE_PRIO_BEST_EFFORT = 1, /** * Urgent traffic (local peer, i.e. conversation). */ GNUNET_CORE_PRIO_URGENT = 2, /** * Highest priority, control traffic (i.e. NSE, Core/Cadet KX). */ GNUNET_CORE_PRIO_CRITICAL_CONTROL = 3 }; /** * Opaque handle to the service. */ struct GNUNET_CORE_Handle; /** * Method called whenever a given peer connects. * * @param cls closure * @param peer peer identity this notification is about * @return closure associated with @a peer. given to mq callbacks and * #GNUNET_CORE_DisconnectEventHandler */ typedef void * (*GNUNET_CORE_ConnectEventHandler) (void *cls, const struct GNUNET_PeerIdentity *peer, struct GNUNET_MQ_Handle *mq); /** * Method called whenever a peer disconnects. * * @param cls closure * @param peer peer identity this notification is about * @param peer_cls closure associated with peer. given in * #GNUNET_CORE_ConnectEventHandler */ typedef void (*GNUNET_CORE_DisconnectEventHandler) (void *cls, const struct GNUNET_PeerIdentity *peer, void *peer_cls); /** * Function called after #GNUNET_CORE_connect has succeeded (or failed * for good). Note that the private key of the peer is intentionally * not exposed here; if you need it, your process should try to read * the private key file directly (which should work if you are * authorized...). Implementations of this function must not call * #GNUNET_CORE_disconnect (other than by scheduling a new task to * do this later). * * @param cls closure * @param my_identity ID of this peer, NULL if we failed */ typedef void (*GNUNET_CORE_StartupCallback) (void *cls, const struct GNUNET_PeerIdentity *my_identity); /** * Connect to the core service. Note that the connection may complete * (or fail) asynchronously. This function primarily causes the given * callback notification functions to be invoked whenever the * specified event happens. The maximum number of queued * notifications (queue length) is per client; the queue is shared * across all types of notifications. So a slow client that registers * for @a outbound_notify also risks missing @a inbound_notify messages. * Certain events (such as connect/disconnect notifications) are not * subject to queue size limitations. * * @param cfg configuration to use * @param cls closure for the various callbacks that follow (including handlers in the handlers array) * @param init callback to call once we have successfully * connected to the core service * @param connects function to call on peer connect, can be NULL * @param disconnects function to call on peer disconnect / timeout, can be NULL * @param handlers callbacks for messages we care about, NULL-terminated * note that the core is allowed to drop notifications about inbound * messages if the client does not process them fast enough (for this * notification type, a bounded queue is used) * @return handle to the core service (only useful for disconnect until @a init is called), * NULL on error (in this case, init is never called) */ struct GNUNET_CORE_Handle * GNUNET_CORE_connect (const struct GNUNET_CONFIGURATION_Handle *cfg, void *cls, GNUNET_CORE_StartupCallback init, GNUNET_CORE_ConnectEventHandler connects, GNUNET_CORE_DisconnectEventHandler disconnects, const struct GNUNET_MQ_MessageHandler *handlers); /** * Disconnect from the core service. * * @param handle connection to core to disconnect */ void GNUNET_CORE_disconnect (struct GNUNET_CORE_Handle *handle); /** * Inquire with CORE what options should be set for a message * so that it is transmitted with the given @a priority and * the given @a cork value. * * @param cork desired corking * @param priority desired message priority * @param[out] flags set to `flags` value for #GNUNET_MQ_set_options() * @return `extra` argument to give to #GNUNET_MQ_set_options() */ const void * GNUNET_CORE_get_mq_options (int cork, enum GNUNET_CORE_Priority priority, uint64_t *flags); /** * Obtain the message queue for a connected peer. * * @param h the core handle * @param pid the identity of the peer * @return NULL if @a pid is not connected */ struct GNUNET_MQ_Handle * GNUNET_CORE_get_mq (const struct GNUNET_CORE_Handle *h, const struct GNUNET_PeerIdentity *pid); /** * Handle to a CORE monitoring operation. */ struct GNUNET_CORE_MonitorHandle; /** * State machine for our P2P encryption handshake. Everyone starts in * #GNUNET_CORE_KX_STATE_DOWN, if we receive the other peer's key * (other peer initiated) we start in state * #GNUNET_CORE_KX_STATE_KEY_RECEIVED (since we will immediately send * our own); otherwise we start in #GNUNET_CORE_KX_STATE_KEY_SENT. If * we get back a PONG from within either state, we move up to * #GNUNET_CORE_KX_STATE_UP (the PONG will always be sent back * encrypted with the key we sent to the other peer). Eventually, * we will try to rekey, for this we will enter * #GNUNET_CORE_KX_STATE_REKEY_SENT until the rekey operation is * confirmed by a PONG from the other peer. */ enum GNUNET_CORE_KxState { /** * No handshake yet. */ GNUNET_CORE_KX_STATE_DOWN = 0, /** * We've sent our session key. */ GNUNET_CORE_KX_STATE_KEY_SENT, /** * We've received the other peers session key. */ GNUNET_CORE_KX_STATE_KEY_RECEIVED, /** * The other peer has confirmed our session key + PING with a PONG * message encrypted with their session key (which we got). Key * exchange is done. */ GNUNET_CORE_KX_STATE_UP, /** * We're rekeying (or had a timeout), so we have sent the other peer * our new ephemeral key, but we did not get a matching PONG yet. * This is equivalent to being #GNUNET_CORE_KX_STATE_KEY_RECEIVED, * except that the session is marked as 'up' with sessions (as we * don't want to drop and re-establish P2P connections simply due to * rekeying). */ GNUNET_CORE_KX_STATE_REKEY_SENT, /** * Last state of a KX (when it is being terminated). Set * just before CORE frees the internal state for this peer. */ GNUNET_CORE_KX_PEER_DISCONNECT, /** * This is not a state in a peer's state machine, but a special * value used with the #GNUNET_CORE_MonitorCallback to indicate * that we finished the initial iteration over the peers. */ GNUNET_CORE_KX_ITERATION_FINISHED, /** * This is not a state in a peer's state machine, but a special * value used with the #GNUNET_CORE_MonitorCallback to indicate * that we lost the connection to the CORE service (and will try * to reconnect). If this happens, most likely the CORE service * crashed and thus all connection state should be assumed lost. */ GNUNET_CORE_KX_CORE_DISCONNECT }; /** * Function called by the monitor callback whenever * a peer's connection status changes. * * @param cls closure * @param pid identity of the peer this update is about * @param state current key exchange state of the peer * @param timeout when does the current state expire */ typedef void (*GNUNET_CORE_MonitorCallback)(void *cls, const struct GNUNET_PeerIdentity *pid, enum GNUNET_CORE_KxState state, struct GNUNET_TIME_Absolute timeout); /** * Monitor connectivity and KX status of all peers known to CORE. * Calls @a peer_cb with the current status for each connected peer, * and then once with NULL to indicate that all peers that are * currently active have been handled. After that, the iteration * continues until it is cancelled. Normal users of the CORE API are * not expected to use this function. It is different in that it * truly lists all connections (including those where the KX is in * progress), not just those relevant to the application. This * function is used by special applications for diagnostics. * * @param cfg configuration handle * @param peer_cb function to call with the peer information * @param peer_cb_cls closure for @a peer_cb * @return NULL on error */ struct GNUNET_CORE_MonitorHandle * GNUNET_CORE_monitor_start (const struct GNUNET_CONFIGURATION_Handle *cfg, GNUNET_CORE_MonitorCallback peer_cb, void *peer_cb_cls); /** * Stop monitoring CORE activity. * * @param mh monitor to stop */ void GNUNET_CORE_monitor_stop (struct GNUNET_CORE_MonitorHandle *mh); /** * Check if the given peer is currently connected. This function is for special * cirumstances (GNUNET_TESTBED uses it), normal users of the CORE API are * expected to track which peers are connected based on the connect/disconnect * callbacks from #GNUNET_CORE_connect. This function is NOT part of the * 'versioned', 'official' API. This function returns * synchronously after looking in the CORE API cache. * * @param h the core handle * @param pid the identity of the peer to check if it has been connected to us * @return #GNUNET_YES if the peer is connected to us; #GNUNET_NO if not */ int GNUNET_CORE_is_peer_connected_sync (const struct GNUNET_CORE_Handle *h, const struct GNUNET_PeerIdentity *pid); /** * Create a message queue for sending messages to a peer with CORE. * Messages may only be queued with #GNUNET_MQ_send once the init callback has * been called for the given handle. * There must only be one queue per peer for each core handle. * The message queue can only be used to transmit messages, * not to receive them. * * @param h the core handle * @param target the target peer for this queue, may not be NULL * @return a message queue for sending messages over the core handle * to the target peer */ struct GNUNET_MQ_Handle * GNUNET_CORE_mq_create (struct GNUNET_CORE_Handle *h, const struct GNUNET_PeerIdentity *target); #if 0 /* keep Emacsens' auto-indent happy */ { #endif #ifdef __cplusplus } #endif /* ifndef GNUNET_CORE_SERVICE_H */ #endif /** @} */ /* end of group core */ /* end of gnunet_core_service.h */