/* This file is part of GNUnet. (C) 2012 Christian Grothoff (and other contributing authors) GNUnet is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, 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 General Public License for more details. You should have received a copy of the GNU General Public License along with GNUnet; see the file COPYING. If not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ /** * @file testbed/gnunet-service-testbed.c * @brief implementation of the TESTBED service * @author Sree Harsha Totakura */ #include "platform.h" #include "gnunet_service_lib.h" #include "gnunet_server_lib.h" #include "gnunet_transport_service.h" #include "gnunet_core_service.h" #include "gnunet_hello_lib.h" #include #include "gnunet_testbed_service.h" #include "testbed.h" #include "testbed_api.h" #include "testbed_api_hosts.h" #include "gnunet_testing_lib-new.h" /** * Generic logging */ #define LOG(kind,...) \ GNUNET_log (kind, __VA_ARGS__) /** * Debug logging */ #define LOG_DEBUG(...) \ LOG (GNUNET_ERROR_TYPE_DEBUG, __VA_ARGS__) /** * By how much should the arrays lists grow */ #define LIST_GROW_STEP 10 /** * Default timeout for operations which may take some time */ #define TIMEOUT GNUNET_TIME_relative_multiply(GNUNET_TIME_UNIT_SECONDS, 30) /** * Timeout of Transport try_connect requests */ #define TRANSPORT_TRY_CONNECT_TIMEOUT \ GNUNET_TIME_relative_multiply(GNUNET_TIME_UNIT_MILLISECONDS, 100) /** * The main context information associated with the client which started us */ struct Context { /** * The client handle associated with this context */ struct GNUNET_SERVER_Client *client; /** * The network address of the master controller */ char *master_ip; /** * The TESTING system handle for starting peers locally */ struct GNUNET_TESTING_System *system; /** * Event mask of event to be responded in this context */ uint64_t event_mask; /** * Our host id according to this context */ uint32_t host_id; }; /** * The message queue for sending messages to clients */ struct MessageQueue { /** * The message to be sent */ struct GNUNET_MessageHeader *msg; /** * The client to send the message to */ struct GNUNET_SERVER_Client *client; /** * next pointer for DLL */ struct MessageQueue *next; /** * prev pointer for DLL */ struct MessageQueue *prev; }; /** * The structure for identifying a shared service */ struct SharedService { /** * The name of the shared service */ char *name; /** * Number of shared peers per instance of the shared service */ uint32_t num_shared; /** * Number of peers currently sharing the service */ uint32_t num_sharing; }; /** * A routing entry */ struct Route { /** * destination host */ uint32_t dest; /** * The destination host is reachable thru */ uint32_t thru; }; /** * Context information used while linking controllers */ struct LinkControllersContext; /** * Structure representing a connected(directly-linked) controller */ struct Slave { /** * The controller process handle if we had started the controller */ struct GNUNET_TESTBED_ControllerProc *controller_proc; /** * The controller handle */ struct GNUNET_TESTBED_Controller *controller; /** * The configuration of the slave. Will be NULL for slave which we didn't * directly start */ struct GNUNET_CONFIGURATION_Handle *cfg; /** * handle to lcc which is associated with this slave startup. Should be set to * NULL when the slave has successfully started up */ struct LinkControllersContext *lcc; /** * The id of the host this controller is running on */ uint32_t host_id; }; /** * States of LCFContext */ enum LCFContextState { /** * The Context has been initialized; Nothing has been done on it */ INIT, /** * Delegated host has been registered at the forwarding controller */ DELEGATED_HOST_REGISTERED, /** * The slave host has been registred at the forwarding controller */ SLAVE_HOST_REGISTERED, /** * The context has been finished (may have error) */ FINISHED }; /** * Link controllers request forwarding context */ struct LCFContext { /** * The gateway which will pass the link message to delegated host */ struct Slave *gateway; /** * The controller link message that has to be forwarded to */ struct GNUNET_TESTBED_ControllerLinkMessage *msg; /** * The client which has asked to perform this operation */ struct GNUNET_SERVER_Client *client; /** * The host registration handle while registered hosts in this context */ struct GNUNET_TESTBED_HostRegistrationHandle *rhandle; /** * The id of the operation which created this context */ uint64_t operation_id; /** * The state of this context */ enum LCFContextState state; /** * The delegated host */ uint32_t delegated_host_id; /** * The slave host */ uint32_t slave_host_id; }; /** * Structure of a queue entry in LCFContext request queue */ struct LCFContextQueue { /** * The LCFContext */ struct LCFContext *lcf; /** * Head prt for DLL */ struct LCFContextQueue *next; /** * Tail ptr for DLL */ struct LCFContextQueue *prev; }; /** * A locally started peer */ struct Peer { union { struct { /** * The peer handle from testing API */ struct GNUNET_TESTING_Peer *peer; /** * The modified (by GNUNET_TESTING_peer_configure) configuration this * peer is configured with */ struct GNUNET_CONFIGURATION_Handle *cfg; /** * Is the peer running */ int is_running; } local; struct { /** * The controller this peer is started through */ struct GNUNET_TESTBED_Controller *controller; } remote; } details; /** * Is this peer locally created? */ int is_remote; /** * Our local reference id for this peer */ uint32_t id; }; /** * Context information for connecting 2 peers in overlay */ struct OverlayConnectContext { /** * The client which has requested for overlay connection */ struct GNUNET_SERVER_Client *client; /** * the peer which has to connect to the other peer */ struct Peer *peer; /** * Transport handle of the first peer to get its HELLO */ struct GNUNET_TRANSPORT_Handle *p1th; /** * Transport handle of other peer to offer first peer's HELLO */ struct GNUNET_TRANSPORT_Handle *p2th; /** * Core handles of the first peer; used to notify when second peer connects to it */ struct GNUNET_CORE_Handle *ch; /** * HELLO of the other peer */ struct GNUNET_MessageHeader *hello; /** * Get hello handle to acquire HELLO of first peer */ struct GNUNET_TRANSPORT_GetHelloHandle *ghh; /** * The error message we send if this overlay connect operation has timed out */ char *emsg; /** * Operation context for suboperations */ struct OperationContext *opc; /** * Controller of peer 2; NULL if the peer is local */ struct GNUNET_TESTBED_Controller *peer2_controller; /** * The peer identity of the first peer */ struct GNUNET_PeerIdentity peer_identity; /** * The peer identity of the other peer */ struct GNUNET_PeerIdentity other_peer_identity; /** * The id of the operation responsible for creating this context */ uint64_t op_id; /** * The id of the task for sending HELLO of peer 2 to peer 1 and ask peer 1 to * connect to peer 2 */ GNUNET_SCHEDULER_TaskIdentifier send_hello_task; /** * The id of the overlay connect timeout task */ GNUNET_SCHEDULER_TaskIdentifier timeout_task; /** * The id of peer A */ uint32_t peer_id; /** * The id of peer B */ uint32_t other_peer_id; }; /** * Context information for RequestOverlayConnect * operations. RequestOverlayConnect is used when peers A, B reside on different * hosts and the host controller for peer B is asked by the host controller of * peer A to make peer B connect to peer A */ struct RequestOverlayConnectContext { /** * The transport handle of peer B */ struct GNUNET_TRANSPORT_Handle *th; /** * Peer A's HELLO */ struct GNUNET_MessageHeader *hello; /** * The peer identity of peer A */ struct GNUNET_PeerIdentity a_id; /** * Task for offering HELLO of A to B and doing try_connect */ GNUNET_SCHEDULER_TaskIdentifier attempt_connect_task_id; /** * Task to timeout RequestOverlayConnect */ GNUNET_SCHEDULER_TaskIdentifier timeout_rocc_task_id; }; /** * Context information for operations forwarded to subcontrollers */ struct ForwardedOperationContext { /** * The generated operation context */ struct OperationContext *opc; /** * The client to which we have to reply */ struct GNUNET_SERVER_Client *client; /** * Closure pointer */ void *cls; /** * Task ID for the timeout task */ GNUNET_SCHEDULER_TaskIdentifier timeout_task; /** * The id of the operation that has been forwarded */ uint64_t operation_id; }; /** * Context information used while linking controllers */ struct LinkControllersContext { /** * The client which initiated the link controller operation */ struct GNUNET_SERVER_Client *client; /** * The ID of the operation */ uint64_t operation_id; }; /** * The master context; generated with the first INIT message */ static struct Context *master_context; /***********/ /* Handles */ /***********/ /** * Current Transmit Handle; NULL if no notify transmit exists currently */ static struct GNUNET_SERVER_TransmitHandle *transmit_handle; /****************/ /* Lists & Maps */ /****************/ /** * The head for the LCF queue */ static struct LCFContextQueue *lcfq_head; /** * The tail for the LCF queue */ static struct LCFContextQueue *lcfq_tail; /** * The message queue head */ static struct MessageQueue *mq_head; /** * The message queue tail */ static struct MessageQueue *mq_tail; /** * Array of host list */ static struct GNUNET_TESTBED_Host **host_list; /** * A list of routes */ static struct Route **route_list; /** * A list of directly linked neighbours */ static struct Slave **slave_list; /** * A list of peers we own locally */ static struct Peer **peer_list; /** * The hashmap of shared services */ static struct GNUNET_CONTAINER_MultiHashMap *ss_map; /** * The size of the host list */ static uint32_t host_list_size; /** * The size of the route list */ static uint32_t route_list_size; /** * The size of directly linked neighbours list */ static uint32_t slave_list_size; /** * The size of the peer list */ static uint32_t peer_list_size; /*********/ /* Tasks */ /*********/ /** * The lcf_task handle */ static GNUNET_SCHEDULER_TaskIdentifier lcf_proc_task_id; /** * The shutdown task handle */ static GNUNET_SCHEDULER_TaskIdentifier shutdown_task_id; /** * Function called to notify a client about the connection begin ready to queue * more data. "buf" will be NULL and "size" zero if the connection was closed * for writing in the meantime. * * @param cls NULL * @param size number of bytes available in buf * @param buf where the callee should write the message * @return number of bytes written to buf */ static size_t transmit_ready_notify (void *cls, size_t size, void *buf) { struct MessageQueue *mq_entry; transmit_handle = NULL; mq_entry = mq_head; GNUNET_assert (NULL != mq_entry); if (0 == size) return 0; GNUNET_assert (ntohs (mq_entry->msg->size) <= size); size = ntohs (mq_entry->msg->size); memcpy (buf, mq_entry->msg, size); GNUNET_free (mq_entry->msg); GNUNET_CONTAINER_DLL_remove (mq_head, mq_tail, mq_entry); GNUNET_free (mq_entry); mq_entry = mq_head; if (NULL != mq_entry) transmit_handle = GNUNET_SERVER_notify_transmit_ready (mq_entry->client, ntohs (mq_entry->msg->size), GNUNET_TIME_UNIT_FOREVER_REL, &transmit_ready_notify, NULL); return size; } /** * Queues a message in send queue for sending to the service * * @param client the client to whom the queued message has to be sent * @param msg the message to queue */ static void queue_message (struct GNUNET_SERVER_Client *client, struct GNUNET_MessageHeader *msg) { struct MessageQueue *mq_entry; uint16_t type; uint16_t size; type = ntohs (msg->type); size = ntohs (msg->size); GNUNET_assert ((GNUNET_MESSAGE_TYPE_TESTBED_INIT <= type) && (GNUNET_MESSAGE_TYPE_TESTBED_MAX > type)); mq_entry = GNUNET_malloc (sizeof (struct MessageQueue)); mq_entry->msg = msg; mq_entry->client = client; LOG_DEBUG ("Queueing message of type %u, size %u for sending\n", type, ntohs (msg->size)); GNUNET_CONTAINER_DLL_insert_tail (mq_head, mq_tail, mq_entry); if (NULL == transmit_handle) transmit_handle = GNUNET_SERVER_notify_transmit_ready (client, size, GNUNET_TIME_UNIT_FOREVER_REL, &transmit_ready_notify, NULL); } /** * Similar to GNUNET_realloc; however clears tail part of newly allocated memory * * @param ptr the memory block to realloc * @param size the size of ptr * @param new_size the size to which ptr has to be realloc'ed * @return the newly reallocated memory block */ static void * TESTBED_realloc (void *ptr, size_t size, size_t new_size) { ptr = GNUNET_realloc (ptr, new_size); if (new_size > size) (void) memset (ptr + size, 0, new_size - size); return ptr; } /** * Function to add a host to the current list of known hosts * * @param host the host to add * @return GNUNET_OK on success; GNUNET_SYSERR on failure due to host-id * already in use */ static int host_list_add (struct GNUNET_TESTBED_Host *host) { uint32_t host_id; uint32_t orig_size; host_id = GNUNET_TESTBED_host_get_id_ (host); orig_size = host_list_size; if (host_list_size <= host_id) { while (host_list_size <= host_id) host_list_size += LIST_GROW_STEP; host_list = TESTBED_realloc (host_list, sizeof (struct GNUNET_TESTBED_Host *) * orig_size, sizeof (struct GNUNET_TESTBED_Host *) * host_list_size); } if (NULL != host_list[host_id]) { LOG_DEBUG ("A host with id: %u already exists\n", host_id); return GNUNET_SYSERR; } host_list[host_id] = host; return GNUNET_OK; } /** * Adds a route to the route list * * @param route the route to add */ static void route_list_add (struct Route *route) { uint32_t orig_size; orig_size = route_list_size; if (route->dest >= route_list_size) { while (route->dest >= route_list_size) route_list_size += LIST_GROW_STEP; route_list = TESTBED_realloc (route_list, sizeof (struct Route *) * orig_size, sizeof (struct Route *) * route_list_size); } GNUNET_assert (NULL == route_list[route->dest]); route_list[route->dest] = route; } /** * Adds a slave to the slave array * * @param slave the slave controller to add */ static void slave_list_add (struct Slave *slave) { if (slave->host_id >= slave_list_size) { slave_list = TESTBED_realloc (slave_list, sizeof (struct Slave *) * slave_list_size, sizeof (struct Slave *) * (slave_list_size + LIST_GROW_STEP)); slave_list_size += LIST_GROW_STEP; } GNUNET_assert (NULL == slave_list[slave->host_id]); slave_list[slave->host_id] = slave; } /** * Adds a peer to the peer array * * @param peer the peer to add */ static void peer_list_add (struct Peer *peer) { uint32_t orig_size; orig_size = peer_list_size; if (peer->id >= peer_list_size) { while (peer->id >= peer_list_size) peer_list_size += LIST_GROW_STEP; peer_list = TESTBED_realloc (peer_list, sizeof (struct Peer *) * orig_size, sizeof (struct Peer *) * peer_list_size); } GNUNET_assert (NULL == peer_list[peer->id]); peer_list[peer->id] = peer; } /** * Removes a the give peer from the peer array * * @param peer the peer to be removed */ static void peer_list_remove (struct Peer *peer) { uint32_t id; uint32_t orig_size; peer_list[peer->id] = NULL; orig_size = peer_list_size; while (peer_list_size >= LIST_GROW_STEP) { for (id = peer_list_size - 1; (id >= peer_list_size - LIST_GROW_STEP) && (id != UINT32_MAX); id--) if (NULL != peer_list[id]) break; if (id != ((peer_list_size - LIST_GROW_STEP) - 1)) break; peer_list_size -= LIST_GROW_STEP; } if (orig_size == peer_list_size) return; peer_list = GNUNET_realloc (peer_list, sizeof (struct Peer *) * peer_list_size); } /** * Finds the route with directly connected host as destination through which * the destination host can be reached * * @param host_id the id of the destination host * @return the route with directly connected destination host; NULL if no route * is found */ static struct Route * find_dest_route (uint32_t host_id) { struct Route *route; while (NULL != (route = route_list[host_id])) { if (route->thru == master_context->host_id) break; host_id = route->thru; } return route; } /** * Routes message to a host given its host_id * * @param host_id the id of the destination host * @param msg the message to be routed */ static void route_message (uint32_t host_id, const struct GNUNET_MessageHeader *msg) { GNUNET_break (0); } /** * Send operation failure message to client * * @param client the client to which the failure message has to be sent to * @param operation_id the id of the failed operation * @param emsg the error message; can be NULL */ static void send_operation_fail_msg (struct GNUNET_SERVER_Client *client, uint64_t operation_id, const char *emsg) { struct GNUNET_TESTBED_OperationFailureEventMessage *msg; uint16_t msize; uint16_t emsg_len; msize = sizeof (struct GNUNET_TESTBED_OperationFailureEventMessage); emsg_len = (NULL == emsg) ? 0 : strlen (emsg) + 1; msize += emsg_len; msg = GNUNET_malloc (msize); msg->header.size = htons (msize); msg->header.type = htons (GNUNET_MESSAGE_TYPE_TESTBED_OPERATIONFAILEVENT); msg->event_type = htonl (GNUNET_TESTBED_ET_OPERATION_FINISHED); msg->operation_id = GNUNET_htonll (operation_id); if (0 != emsg_len) memcpy (&msg[1], emsg, emsg_len); queue_message (client, &msg->header); } /** * Function to send generic operation success message to given client * * @param client the client to send the message to * @param operation_id the id of the operation which was successful */ static void send_operation_success_msg (struct GNUNET_SERVER_Client *client, uint64_t operation_id) { struct GNUNET_TESTBED_GenericOperationSuccessEventMessage *msg; uint16_t msize; msize = sizeof (struct GNUNET_TESTBED_GenericOperationSuccessEventMessage); msg = GNUNET_malloc (msize); msg->header.size = htons (msize); msg->header.type = htons (GNUNET_MESSAGE_TYPE_TESTBED_GENERICOPSUCCESS); msg->operation_id = GNUNET_htonll (operation_id); msg->event_type = htonl (GNUNET_TESTBED_ET_OPERATION_FINISHED); queue_message (client, &msg->header); } /** * The Link Controller forwarding task * * @param cls the LCFContext * @param tc the Task context from scheduler */ static void lcf_proc_task (void *cls, const struct GNUNET_SCHEDULER_TaskContext *tc); /** * Completion callback for host registrations while forwarding Link Controller messages * * @param cls the LCFContext * @param emsg the error message; NULL if host registration is successful */ static void lcf_proc_cc (void *cls, const char *emsg) { struct LCFContext *lcf = cls; lcf->rhandle = NULL; GNUNET_assert (GNUNET_SCHEDULER_NO_TASK == lcf_proc_task_id); switch (lcf->state) { case INIT: if (NULL != emsg) goto registration_error; lcf->state = DELEGATED_HOST_REGISTERED; lcf_proc_task_id = GNUNET_SCHEDULER_add_now (&lcf_proc_task, lcf); break; case DELEGATED_HOST_REGISTERED: if (NULL != emsg) goto registration_error; lcf->state = SLAVE_HOST_REGISTERED; lcf_proc_task_id = GNUNET_SCHEDULER_add_now (&lcf_proc_task, lcf); break; default: GNUNET_assert (0); /* Shouldn't reach here */ } return; registration_error: LOG (GNUNET_ERROR_TYPE_WARNING, "Host registration failed with message: %s\n", emsg); lcf->state = FINISHED; lcf_proc_task_id = GNUNET_SCHEDULER_add_now (&lcf_proc_task, lcf); } /** * Callback to be called when forwarded link controllers operation is * successfull. We have to relay the reply msg back to the client * * @param cls ForwardedOperationContext * @param msg the peer create success message */ static void forwarded_operation_reply_relay (void *cls, const struct GNUNET_MessageHeader *msg) { struct ForwardedOperationContext *fopc = cls; struct GNUNET_MessageHeader *dup_msg; uint16_t msize; msize = ntohs (msg->size); LOG_DEBUG ("Relaying message with type: %u, size: %u\n", ntohs (msg->type), msize); dup_msg = GNUNET_malloc (msize); (void) memcpy (dup_msg, msg, msize); queue_message (fopc->client, dup_msg); GNUNET_SERVER_client_drop (fopc->client); GNUNET_SCHEDULER_cancel (fopc->timeout_task); GNUNET_free (fopc); } /** * Task to free resources when forwarded link controllers has been timedout * * @param cls the ForwardedOperationContext * @param tc the task context from scheduler */ static void forwarded_operation_timeout (void *cls, const struct GNUNET_SCHEDULER_TaskContext *tc) { struct ForwardedOperationContext *fopc = cls; GNUNET_TESTBED_forward_operation_msg_cancel_ (fopc->opc); send_operation_fail_msg (fopc->client, fopc->operation_id, "Timeout"); GNUNET_SERVER_client_drop (fopc->client); GNUNET_free (fopc); } /** * The Link Controller forwarding task * * @param cls the LCFContext * @param tc the Task context from scheduler */ static void lcf_proc_task (void *cls, const struct GNUNET_SCHEDULER_TaskContext *tc) { struct LCFContext *lcf = cls; struct LCFContextQueue *lcfq; struct ForwardedOperationContext *fopc; lcf_proc_task_id = GNUNET_SCHEDULER_NO_TASK; switch (lcf->state) { case INIT: if (GNUNET_NO == GNUNET_TESTBED_is_host_registered_ (host_list[lcf->delegated_host_id], lcf->gateway->controller)) { lcf->rhandle = GNUNET_TESTBED_register_host (lcf->gateway->controller, host_list[lcf->delegated_host_id], lcf_proc_cc, lcf); } else { lcf->state = DELEGATED_HOST_REGISTERED; lcf_proc_task_id = GNUNET_SCHEDULER_add_now (&lcf_proc_task, lcf); } break; case DELEGATED_HOST_REGISTERED: if (GNUNET_NO == GNUNET_TESTBED_is_host_registered_ (host_list[lcf->slave_host_id], lcf->gateway->controller)) { lcf->rhandle = GNUNET_TESTBED_register_host (lcf->gateway->controller, host_list[lcf->slave_host_id], lcf_proc_cc, lcf); } else { lcf->state = SLAVE_HOST_REGISTERED; lcf_proc_task_id = GNUNET_SCHEDULER_add_now (&lcf_proc_task, lcf); } break; case SLAVE_HOST_REGISTERED: fopc = GNUNET_malloc (sizeof (struct ForwardedOperationContext)); fopc->client = lcf->client; fopc->operation_id = lcf->operation_id; fopc->opc = GNUNET_TESTBED_forward_operation_msg_ (lcf->gateway->controller, lcf->operation_id, &lcf->msg->header, &forwarded_operation_reply_relay, fopc); fopc->timeout_task = GNUNET_SCHEDULER_add_delayed (TIMEOUT, &forwarded_operation_timeout, fopc); lcf->state = FINISHED; lcf_proc_task_id = GNUNET_SCHEDULER_add_now (&lcf_proc_task, lcf); break; case FINISHED: lcfq = lcfq_head; GNUNET_assert (lcfq->lcf == lcf); GNUNET_free (lcf->msg); GNUNET_free (lcf); GNUNET_CONTAINER_DLL_remove (lcfq_head, lcfq_tail, lcfq); GNUNET_free (lcfq); if (NULL != lcfq_head) lcf_proc_task_id = GNUNET_SCHEDULER_add_now (&lcf_proc_task, lcfq_head->lcf); } } /** * Callback for event from slave controllers * * @param cls struct Slave * * @param event information about the event */ static void slave_event_callback (void *cls, const struct GNUNET_TESTBED_EventInformation *event) { GNUNET_break (0); } /** * Callback to signal successfull startup of the controller process * * @param cls the handle to the slave whose status is to be found here * @param cfg the configuration with which the controller has been started; * NULL if status is not GNUNET_OK * @param status GNUNET_OK if the startup is successfull; GNUNET_SYSERR if not, * GNUNET_TESTBED_controller_stop() shouldn't be called in this case */ static void slave_status_callback (void *cls, const struct GNUNET_CONFIGURATION_Handle *cfg, int status) { struct Slave *slave = cls; struct LinkControllersContext *lcc; lcc = slave->lcc; if (GNUNET_SYSERR == status) { slave->controller_proc = NULL; slave_list[slave->host_id] = NULL; if (NULL != slave->cfg) GNUNET_CONFIGURATION_destroy (slave->cfg); GNUNET_free (slave); slave = NULL; LOG (GNUNET_ERROR_TYPE_WARNING, "Unexpected slave shutdown\n"); GNUNET_SCHEDULER_shutdown (); /* We too shutdown */ goto clean_lcc; } slave->controller = GNUNET_TESTBED_controller_connect (cfg, host_list[slave->host_id], master_context->event_mask, &slave_event_callback, slave); if (NULL != slave->controller) { send_operation_success_msg (lcc->client, lcc->operation_id); slave->cfg = GNUNET_CONFIGURATION_dup (cfg); } else { send_operation_fail_msg (lcc->client, lcc->operation_id, "Could not connect to delegated controller"); GNUNET_TESTBED_controller_stop (slave->controller_proc); slave_list[slave->host_id] = NULL; GNUNET_free (slave); slave = NULL; } clean_lcc: if (NULL != lcc) { if (NULL != lcc->client) { GNUNET_SERVER_receive_done (lcc->client, GNUNET_OK); GNUNET_SERVER_client_drop (lcc->client); lcc->client = NULL; } GNUNET_free (lcc); } if (NULL != slave) slave->lcc = NULL; } /** * Message handler for GNUNET_MESSAGE_TYPE_TESTBED_INIT messages * * @param cls NULL * @param client identification of the client * @param message the actual message */ static void handle_init (void *cls, struct GNUNET_SERVER_Client *client, const struct GNUNET_MessageHeader *message) { const struct GNUNET_TESTBED_InitMessage *msg; struct GNUNET_TESTBED_Host *host; const char *controller_hostname; uint16_t msize; if (NULL != master_context) { LOG_DEBUG ("We are being connected to laterally\n"); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } msg = (const struct GNUNET_TESTBED_InitMessage *) message; msize = ntohs (message->size); if (msize <= sizeof (struct GNUNET_TESTBED_InitMessage)) { GNUNET_break (0); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } msize -= sizeof (struct GNUNET_TESTBED_InitMessage); controller_hostname = (const char *) &msg[1]; if ('\0' != controller_hostname[msize - 1]) { GNUNET_break (0); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } master_context = GNUNET_malloc (sizeof (struct Context)); master_context->client = client; master_context->host_id = ntohl (msg->host_id); master_context->master_ip = GNUNET_strdup (controller_hostname); LOG_DEBUG ("Master Controller IP: %s\n", master_context->master_ip); master_context->system = GNUNET_TESTING_system_create ("testbed", master_context->master_ip); host = GNUNET_TESTBED_host_create_with_id (master_context->host_id, NULL, NULL, 0); host_list_add (host); master_context->event_mask = GNUNET_ntohll (msg->event_mask); GNUNET_SERVER_client_keep (client); LOG_DEBUG ("Created master context with host ID: %u\n", master_context->host_id); GNUNET_SERVER_receive_done (client, GNUNET_OK); } /** * Message handler for GNUNET_MESSAGE_TYPE_TESTBED_ADDHOST messages * * @param cls NULL * @param client identification of the client * @param message the actual message */ static void handle_add_host (void *cls, struct GNUNET_SERVER_Client *client, const struct GNUNET_MessageHeader *message) { struct GNUNET_TESTBED_Host *host; const struct GNUNET_TESTBED_AddHostMessage *msg; struct GNUNET_TESTBED_HostConfirmedMessage *reply; char *username; char *hostname; char *emsg; uint32_t host_id; uint16_t username_length; uint16_t hostname_length; uint16_t reply_size; uint16_t msize; msg = (const struct GNUNET_TESTBED_AddHostMessage *) message; msize = ntohs (msg->header.size); username = (char *) &(msg[1]); username_length = ntohs (msg->user_name_length); GNUNET_assert (msize > (sizeof (struct GNUNET_TESTBED_AddHostMessage) + username_length + 1)); /* msg must contain hostname */ if (0 != username_length) GNUNET_assert ('\0' == username[username_length]); username_length = (0 == username_length) ? 0 : username_length + 1; hostname = username + username_length; hostname_length = msize - (sizeof (struct GNUNET_TESTBED_AddHostMessage) + username_length); GNUNET_assert ('\0' == hostname[hostname_length - 1]); GNUNET_assert (strlen (hostname) == hostname_length - 1); host_id = ntohl (msg->host_id); LOG_DEBUG ("Received ADDHOST message\n"); LOG_DEBUG ("-------host id: %u\n", host_id); LOG_DEBUG ("-------hostname: %s\n", hostname); if (0 != username_length) LOG_DEBUG ("-------username: %s\n", username); else { LOG_DEBUG ("-------username: NULL\n"); username = NULL; } LOG_DEBUG ("-------ssh port: %u\n", ntohs (msg->ssh_port)); host = GNUNET_TESTBED_host_create_with_id (host_id, hostname, username, ntohs (msg->ssh_port)); GNUNET_assert (NULL != host); GNUNET_SERVER_receive_done (client, GNUNET_OK); reply_size = sizeof (struct GNUNET_TESTBED_HostConfirmedMessage); if (GNUNET_OK != host_list_add (host)) { /* We are unable to add a host */ emsg = "A host exists with given host-id"; LOG_DEBUG ("%s: %u", emsg, host_id); GNUNET_TESTBED_host_destroy (host); reply_size += strlen (emsg) + 1; reply = GNUNET_malloc (reply_size); memcpy (&reply[1], emsg, strlen (emsg) + 1); } else reply = GNUNET_malloc (reply_size); reply->header.type = htons (GNUNET_MESSAGE_TYPE_TESTBED_ADDHOSTCONFIRM); reply->header.size = htons (reply_size); reply->host_id = htonl (host_id); queue_message (client, &reply->header); } /** * Iterator over hash map entries. * * @param cls closure * @param key current key code * @param value value in the hash map * @return GNUNET_YES if we should continue to * iterate, * GNUNET_NO if not. */ int ss_exists_iterator (void *cls, const struct GNUNET_HashCode *key, void *value) { struct SharedService *queried_ss = cls; struct SharedService *ss = value; if (0 == strcmp (ss->name, queried_ss->name)) return GNUNET_NO; else return GNUNET_YES; } /** * Message handler for GNUNET_MESSAGE_TYPE_TESTBED_ADDHOST messages * * @param cls NULL * @param client identification of the client * @param message the actual message */ static void handle_configure_shared_service (void *cls, struct GNUNET_SERVER_Client *client, const struct GNUNET_MessageHeader *message) { const struct GNUNET_TESTBED_ConfigureSharedServiceMessage *msg; struct SharedService *ss; char *service_name; struct GNUNET_HashCode hash; uint16_t msg_size; uint16_t service_name_size; msg = (const struct GNUNET_TESTBED_ConfigureSharedServiceMessage *) message; msg_size = ntohs (message->size); if (msg_size <= sizeof (struct GNUNET_TESTBED_ConfigureSharedServiceMessage)) { GNUNET_break (0); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } service_name_size = msg_size - sizeof (struct GNUNET_TESTBED_ConfigureSharedServiceMessage); service_name = (char *) &msg[1]; if ('\0' != service_name[service_name_size - 1]) { GNUNET_break (0); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } LOG_DEBUG ("Received service sharing request for %s, with %d peers\n", service_name, ntohl (msg->num_peers)); if (ntohl (msg->host_id) != master_context->host_id) { route_message (ntohl (msg->host_id), message); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } GNUNET_SERVER_receive_done (client, GNUNET_OK); ss = GNUNET_malloc (sizeof (struct SharedService)); ss->name = strdup (service_name); ss->num_shared = ntohl (msg->num_peers); GNUNET_CRYPTO_hash (ss->name, service_name_size, &hash); if (GNUNET_SYSERR == GNUNET_CONTAINER_multihashmap_get_multiple (ss_map, &hash, &ss_exists_iterator, ss)) { LOG (GNUNET_ERROR_TYPE_WARNING, "Service %s already configured as a shared service. " "Ignoring service sharing request \n", ss->name); GNUNET_free (ss->name); GNUNET_free (ss); return; } GNUNET_CONTAINER_multihashmap_put (ss_map, &hash, ss, GNUNET_CONTAINER_MULTIHASHMAPOPTION_MULTIPLE); } /** * Message handler for GNUNET_MESSAGE_TYPE_TESTBED_LCONTROLLERS message * * @param cls NULL * @param client identification of the client * @param message the actual message */ static void handle_link_controllers (void *cls, struct GNUNET_SERVER_Client *client, const struct GNUNET_MessageHeader *message) { const struct GNUNET_TESTBED_ControllerLinkMessage *msg; struct GNUNET_CONFIGURATION_Handle *cfg; struct LCFContextQueue *lcfq; struct Route *route; struct Route *new_route; char *config; uLongf dest_size; size_t config_size; uint32_t delegated_host_id; uint32_t slave_host_id; uint16_t msize; if (NULL == master_context) { GNUNET_break (0); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } msize = ntohs (message->size); if (sizeof (struct GNUNET_TESTBED_ControllerLinkMessage) >= msize) { GNUNET_break (0); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } msg = (const struct GNUNET_TESTBED_ControllerLinkMessage *) message; delegated_host_id = ntohl (msg->delegated_host_id); if (delegated_host_id == master_context->host_id) { GNUNET_break (0); LOG (GNUNET_ERROR_TYPE_WARNING, "Trying to link ourselves\n"); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } if ((delegated_host_id >= host_list_size) || (NULL == host_list[delegated_host_id])) { LOG (GNUNET_ERROR_TYPE_WARNING, "Delegated host %u not registered with us\n", delegated_host_id); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } slave_host_id = ntohl (msg->slave_host_id); if ((slave_host_id >= host_list_size) || (NULL == host_list[slave_host_id])) { LOG (GNUNET_ERROR_TYPE_WARNING, "Slave host not registered with us\n"); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } if (slave_host_id == delegated_host_id) { LOG (GNUNET_ERROR_TYPE_WARNING, "Slave and delegated host are same\n"); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } if (slave_host_id == master_context->host_id) /* Link from us */ { struct Slave *slave; struct LinkControllersContext *lcc; msize -= sizeof (struct GNUNET_TESTBED_ControllerLinkMessage); config_size = ntohs (msg->config_size); if ((delegated_host_id < slave_list_size) && (NULL != slave_list[delegated_host_id])) /* We have already added */ { LOG (GNUNET_ERROR_TYPE_WARNING, "Host %u already connected\n", delegated_host_id); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } config = GNUNET_malloc (config_size); dest_size = (uLongf) config_size; if (Z_OK != uncompress ((Bytef *) config, &dest_size, (const Bytef *) &msg[1], (uLong) msize)) { GNUNET_break (0); /* Compression error */ GNUNET_free (config); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } if (config_size != dest_size) { LOG (GNUNET_ERROR_TYPE_WARNING, "Uncompressed config size mismatch\n"); GNUNET_free (config); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } cfg = GNUNET_CONFIGURATION_create (); /* Free here or in lcfcontext */ if (GNUNET_OK != GNUNET_CONFIGURATION_deserialize (cfg, config, config_size, GNUNET_NO)) { GNUNET_break (0); /* Configuration parsing error */ GNUNET_free (config); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } GNUNET_free (config); if ((delegated_host_id < slave_list_size) && (NULL != slave_list[delegated_host_id])) { GNUNET_break (0); /* Configuration parsing error */ GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } slave = GNUNET_malloc (sizeof (struct Slave)); slave->host_id = delegated_host_id; slave_list_add (slave); if (1 != msg->is_subordinate) { slave->controller = GNUNET_TESTBED_controller_connect (cfg, host_list[slave->host_id], master_context->event_mask, &slave_event_callback, slave); GNUNET_CONFIGURATION_destroy (cfg); if (NULL != slave->controller) send_operation_success_msg (client, GNUNET_ntohll (msg->operation_id)); else send_operation_fail_msg (client, GNUNET_ntohll (msg->operation_id), "Could not connect to delegated controller"); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } lcc = GNUNET_malloc (sizeof (struct LinkControllersContext)); lcc->operation_id = GNUNET_ntohll (msg->operation_id); GNUNET_SERVER_client_keep (client); lcc->client = client; slave->lcc = lcc; slave->controller_proc = GNUNET_TESTBED_controller_start (master_context->master_ip, host_list[slave->host_id], cfg, &slave_status_callback, slave); GNUNET_CONFIGURATION_destroy (cfg); new_route = GNUNET_malloc (sizeof (struct Route)); new_route->dest = delegated_host_id; new_route->thru = master_context->host_id; route_list_add (new_route); return; } /* Route the request */ if (slave_host_id >= route_list_size) { LOG (GNUNET_ERROR_TYPE_WARNING, "No route towards slave host"); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } lcfq = GNUNET_malloc (sizeof (struct LCFContextQueue)); lcfq->lcf = GNUNET_malloc (sizeof (struct LCFContext)); lcfq->lcf->delegated_host_id = delegated_host_id; lcfq->lcf->slave_host_id = slave_host_id; route = find_dest_route (slave_host_id); GNUNET_assert (NULL != route); /* because we add routes carefully */ GNUNET_assert (route->dest < slave_list_size); GNUNET_assert (NULL != slave_list[route->dest]); lcfq->lcf->state = INIT; lcfq->lcf->operation_id = GNUNET_ntohll (msg->operation_id); lcfq->lcf->gateway = slave_list[route->dest]; lcfq->lcf->msg = GNUNET_malloc (msize); (void) memcpy (lcfq->lcf->msg, msg, msize); GNUNET_SERVER_client_keep (client); lcfq->lcf->client = client; if (NULL == lcfq_head) { GNUNET_assert (GNUNET_SCHEDULER_NO_TASK == lcf_proc_task_id); GNUNET_CONTAINER_DLL_insert_tail (lcfq_head, lcfq_tail, lcfq); lcf_proc_task_id = GNUNET_SCHEDULER_add_now (&lcf_proc_task, lcfq->lcf); } else GNUNET_CONTAINER_DLL_insert_tail (lcfq_head, lcfq_tail, lcfq); /* FIXME: Adding a new route should happen after the controllers are linked * successfully */ if (1 != msg->is_subordinate) { GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } if ((delegated_host_id < route_list_size) && (NULL != route_list[delegated_host_id])) { GNUNET_break_op (0); /* Are you trying to link delegated host twice with is subordinate flag set to GNUNET_YES? */ GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } new_route = GNUNET_malloc (sizeof (struct Route)); new_route->dest = delegated_host_id; new_route->thru = route->dest; route_list_add (new_route); GNUNET_SERVER_receive_done (client, GNUNET_OK); } /** * The task to be executed if the forwarded peer create operation has been * timed out * * @param cls the FowardedOperationContext * @param tc the TaskContext from the scheduler */ static void peer_create_forward_timeout (void *cls, const struct GNUNET_SCHEDULER_TaskContext *tc) { struct ForwardedOperationContext *fo_ctxt = cls; /* send error msg to client */ send_operation_fail_msg (fo_ctxt->client, fo_ctxt->operation_id, "Timedout"); GNUNET_SERVER_client_drop (fo_ctxt->client); GNUNET_TESTBED_forward_operation_msg_cancel_ (fo_ctxt->opc); GNUNET_free (fo_ctxt); } /** * Callback to be called when forwarded peer create operation is * successfull. We have to relay the reply msg back to the client * * @param cls ForwardedOperationContext * @param msg the peer create success message */ static void peer_create_success_cb (void *cls, const struct GNUNET_MessageHeader *msg) { struct ForwardedOperationContext *fo_ctxt = cls; const struct GNUNET_TESTBED_PeerCreateSuccessEventMessage *success_msg; struct GNUNET_MessageHeader *dup_msg; struct Peer *peer; uint16_t msize; GNUNET_SCHEDULER_cancel (fo_ctxt->timeout_task); if (ntohs (msg->type) == GNUNET_MESSAGE_TYPE_TESTBED_PEERCREATESUCCESS) { success_msg = (const struct GNUNET_TESTBED_PeerCreateSuccessEventMessage *) msg; peer = GNUNET_malloc (sizeof (struct Peer)); peer->is_remote = GNUNET_YES; peer->id = ntohl (success_msg->peer_id); GNUNET_assert (NULL != fo_ctxt->cls); peer->details.remote.controller = fo_ctxt->cls; peer_list_add (peer); } msize = ntohs (msg->size); dup_msg = GNUNET_malloc (msize); (void) memcpy (dup_msg, msg, msize); queue_message (fo_ctxt->client, dup_msg); GNUNET_SERVER_client_drop (fo_ctxt->client); GNUNET_free (fo_ctxt); } /** * Handler for GNUNET_MESSAGE_TYPE_TESTBED_CREATEPEER messages * * @param cls NULL * @param client identification of the client * @param message the actual message */ static void handle_peer_create (void *cls, struct GNUNET_SERVER_Client *client, const struct GNUNET_MessageHeader *message) { const struct GNUNET_TESTBED_PeerCreateMessage *msg; struct GNUNET_TESTBED_PeerCreateSuccessEventMessage *reply; struct GNUNET_CONFIGURATION_Handle *cfg; struct ForwardedOperationContext *fo_ctxt; struct Route *route; struct Peer *peer; char *config; size_t dest_size; int ret; uint32_t config_size; uint32_t host_id; uint32_t peer_id; uint16_t msize; msize = ntohs (message->size); if (msize <= sizeof (struct GNUNET_TESTBED_PeerCreateMessage)) { GNUNET_break (0); /* We need configuration */ GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } msg = (const struct GNUNET_TESTBED_PeerCreateMessage *) message; host_id = ntohl (msg->host_id); peer_id = ntohl (msg->peer_id); if (UINT32_MAX == peer_id) { send_operation_fail_msg (client, GNUNET_ntohll (msg->operation_id), "Cannot create peer with given ID"); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } if (host_id == master_context->host_id) { char *emsg; /* We are responsible for this peer */ msize -= sizeof (struct GNUNET_TESTBED_PeerCreateMessage); config_size = ntohl (msg->config_size); config = GNUNET_malloc (config_size); dest_size = config_size; if (Z_OK != (ret = uncompress ((Bytef *) config, (uLongf *) & dest_size, (const Bytef *) &msg[1], (uLong) msize))) { GNUNET_break (0); /* uncompression error */ GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } if (config_size != dest_size) { GNUNET_break (0); /* Uncompressed config size mismatch */ GNUNET_free (config); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } cfg = GNUNET_CONFIGURATION_create (); if (GNUNET_OK != GNUNET_CONFIGURATION_deserialize (cfg, config, config_size, GNUNET_NO)) { GNUNET_break (0); /* Configuration parsing error */ GNUNET_free (config); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } GNUNET_free (config); peer = GNUNET_malloc (sizeof (struct Peer)); peer->is_remote = GNUNET_NO; peer->details.local.cfg = cfg; peer->id = peer_id; LOG_DEBUG ("Creating peer with id: %u\n", peer->id); peer->details.local.peer = GNUNET_TESTING_peer_configure (master_context->system, peer->details.local.cfg, peer->id, NULL /* Peer id */ , &emsg); if (NULL == peer->details.local.peer) { LOG (GNUNET_ERROR_TYPE_WARNING, "Configuring peer failed: %s\n", emsg); GNUNET_free (emsg); GNUNET_free (peer); GNUNET_break (0); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } peer->details.local.is_running = GNUNET_NO; peer_list_add (peer); reply = GNUNET_malloc (sizeof (struct GNUNET_TESTBED_PeerCreateSuccessEventMessage)); reply->header.size = htons (sizeof (struct GNUNET_TESTBED_PeerCreateSuccessEventMessage)); reply->header.type = htons (GNUNET_MESSAGE_TYPE_TESTBED_PEERCREATESUCCESS); reply->peer_id = msg->peer_id; reply->operation_id = msg->operation_id; queue_message (client, &reply->header); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } /* Forward peer create request */ route = find_dest_route (host_id); if (NULL == route) { GNUNET_break (0); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } fo_ctxt = GNUNET_malloc (sizeof (struct ForwardedOperationContext)); GNUNET_SERVER_client_keep (client); fo_ctxt->client = client; fo_ctxt->operation_id = GNUNET_ntohll (msg->operation_id); fo_ctxt->cls = slave_list[route->dest]->controller; fo_ctxt->opc = GNUNET_TESTBED_forward_operation_msg_ (slave_list [route->dest]->controller, fo_ctxt->operation_id, &msg->header, peer_create_success_cb, fo_ctxt); fo_ctxt->timeout_task = GNUNET_SCHEDULER_add_delayed (TIMEOUT, &peer_create_forward_timeout, fo_ctxt); GNUNET_SERVER_receive_done (client, GNUNET_OK); } /** * Message handler for GNUNET_MESSAGE_TYPE_TESTBED_DESTROYPEER messages * * @param cls NULL * @param client identification of the client * @param message the actual message */ static void handle_peer_destroy (void *cls, struct GNUNET_SERVER_Client *client, const struct GNUNET_MessageHeader *message) { const struct GNUNET_TESTBED_PeerDestroyMessage *msg; struct ForwardedOperationContext *fopc; struct Peer *peer; uint32_t peer_id; msg = (const struct GNUNET_TESTBED_PeerDestroyMessage *) message; peer_id = ntohl (msg->peer_id); LOG_DEBUG ("Received peer destory on peer: %u and operation id: %ul\n", peer_id, GNUNET_ntohll (msg->operation_id)); if ((peer_list_size <= peer_id) || (NULL == peer_list[peer_id])) { LOG (GNUNET_ERROR_TYPE_ERROR, "Asked to destroy a non existent peer with id: %u\n", peer_id); send_operation_fail_msg (client, GNUNET_ntohll (msg->operation_id), "Peer doesn't exist"); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } peer = peer_list[peer_id]; if (GNUNET_YES == peer->is_remote) { /* Forward the destory message to sub controller */ fopc = GNUNET_malloc (sizeof (struct ForwardedOperationContext)); GNUNET_SERVER_client_keep (client); fopc->client = client; fopc->operation_id = GNUNET_ntohll (msg->operation_id); fopc->opc = GNUNET_TESTBED_forward_operation_msg_ (peer->details.remote.controller, fopc->operation_id, &msg->header, &forwarded_operation_reply_relay, fopc); fopc->timeout_task = GNUNET_SCHEDULER_add_delayed (TIMEOUT, &forwarded_operation_timeout, fopc); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } GNUNET_TESTING_peer_destroy (peer->details.local.peer); GNUNET_CONFIGURATION_destroy (peer->details.local.cfg); peer_list_remove (peer); GNUNET_free (peer); send_operation_success_msg (client, GNUNET_ntohll (msg->operation_id)); GNUNET_SERVER_receive_done (client, GNUNET_OK); } /** * Message handler for GNUNET_MESSAGE_TYPE_TESTBED_DESTROYPEER messages * * @param cls NULL * @param client identification of the client * @param message the actual message */ static void handle_peer_start (void *cls, struct GNUNET_SERVER_Client *client, const struct GNUNET_MessageHeader *message) { const struct GNUNET_TESTBED_PeerStartMessage *msg; struct GNUNET_TESTBED_PeerEventMessage *reply; struct ForwardedOperationContext *fopc; struct Peer *peer; uint32_t peer_id; msg = (const struct GNUNET_TESTBED_PeerStartMessage *) message; peer_id = ntohl (msg->peer_id); if ((peer_id >= peer_list_size) || (NULL == peer_list[peer_id])) { GNUNET_break (0); LOG (GNUNET_ERROR_TYPE_ERROR, "Asked to start a non existent peer with id: %u\n", peer_id); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } peer = peer_list[peer_id]; if (GNUNET_YES == peer->is_remote) { fopc = GNUNET_malloc (sizeof (struct ForwardedOperationContext)); GNUNET_SERVER_client_keep (client); fopc->client = client; fopc->operation_id = GNUNET_ntohll (msg->operation_id); fopc->opc = GNUNET_TESTBED_forward_operation_msg_ (peer->details.remote.controller, fopc->operation_id, &msg->header, &forwarded_operation_reply_relay, fopc); fopc->timeout_task = GNUNET_SCHEDULER_add_delayed (TIMEOUT, &forwarded_operation_timeout, fopc); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } if (GNUNET_OK != GNUNET_TESTING_peer_start (peer->details.local.peer)) { send_operation_fail_msg (client, GNUNET_ntohll (msg->operation_id), "Failed to start"); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } peer->details.local.is_running = GNUNET_YES; reply = GNUNET_malloc (sizeof (struct GNUNET_TESTBED_PeerEventMessage)); reply->header.type = htons (GNUNET_MESSAGE_TYPE_TESTBED_PEEREVENT); reply->header.size = htons (sizeof (struct GNUNET_TESTBED_PeerEventMessage)); reply->event_type = htonl (GNUNET_TESTBED_ET_PEER_START); reply->host_id = htonl (master_context->host_id); reply->peer_id = msg->peer_id; reply->operation_id = msg->operation_id; queue_message (client, &reply->header); GNUNET_SERVER_receive_done (client, GNUNET_OK); } /** * Message handler for GNUNET_MESSAGE_TYPE_TESTBED_DESTROYPEER messages * * @param cls NULL * @param client identification of the client * @param message the actual message */ static void handle_peer_stop (void *cls, struct GNUNET_SERVER_Client *client, const struct GNUNET_MessageHeader *message) { const struct GNUNET_TESTBED_PeerStopMessage *msg; struct GNUNET_TESTBED_PeerEventMessage *reply; struct ForwardedOperationContext *fopc; struct Peer *peer; uint32_t peer_id; msg = (const struct GNUNET_TESTBED_PeerStopMessage *) message; peer_id = ntohl (msg->peer_id); if ((peer_id >= peer_list_size) || (NULL == peer_list[peer_id])) { send_operation_fail_msg (client, GNUNET_ntohll (msg->operation_id), "Peer not found"); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } peer = peer_list[peer_id]; if (GNUNET_YES == peer->is_remote) { fopc = GNUNET_malloc (sizeof (struct ForwardedOperationContext)); GNUNET_SERVER_client_keep (client); fopc->client = client; fopc->operation_id = GNUNET_ntohll (msg->operation_id); fopc->opc = GNUNET_TESTBED_forward_operation_msg_ (peer->details.remote.controller, fopc->operation_id, &msg->header, &forwarded_operation_reply_relay, fopc); fopc->timeout_task = GNUNET_SCHEDULER_add_delayed (TIMEOUT, &forwarded_operation_timeout, fopc); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } if (GNUNET_OK != GNUNET_TESTING_peer_stop (peer->details.local.peer)) { send_operation_fail_msg (client, GNUNET_ntohll (msg->operation_id), "Peer not running"); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } peer->details.local.is_running = GNUNET_NO; reply = GNUNET_malloc (sizeof (struct GNUNET_TESTBED_PeerEventMessage)); reply->header.type = htons (GNUNET_MESSAGE_TYPE_TESTBED_PEEREVENT); reply->header.size = htons (sizeof (struct GNUNET_TESTBED_PeerEventMessage)); reply->event_type = htonl (GNUNET_TESTBED_ET_PEER_STOP); reply->host_id = htonl (master_context->host_id); reply->peer_id = msg->peer_id; reply->operation_id = msg->operation_id; queue_message (client, &reply->header); GNUNET_SERVER_receive_done (client, GNUNET_OK); } /** * Handler for GNUNET_MESSAGE_TYPE_TESTBED_GETPEERCONFIG messages * * @param cls NULL * @param client identification of the client * @param message the actual message */ static void handle_peer_get_config (void *cls, struct GNUNET_SERVER_Client *client, const struct GNUNET_MessageHeader *message) { const struct GNUNET_TESTBED_PeerGetConfigurationMessage *msg; struct GNUNET_TESTBED_PeerConfigurationInformationMessage *reply; struct Peer *peer; char *config; char *xconfig; size_t c_size; size_t xc_size; uint32_t peer_id; uint16_t msize; msg = (const struct GNUNET_TESTBED_PeerGetConfigurationMessage *) message; peer_id = ntohl (msg->peer_id); if ((peer_id >= peer_list_size) || (NULL == peer_list[peer_id])) { send_operation_fail_msg (client, GNUNET_ntohll (msg->operation_id), "Peer not found"); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } peer = peer_list[peer_id]; if (GNUNET_YES == peer->is_remote) { /* FIXME: forward to sub controller */ GNUNET_break (0); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } config = GNUNET_CONFIGURATION_serialize (peer_list[peer_id]->details.local.cfg, &c_size); xc_size = GNUNET_TESTBED_compress_config_ (config, c_size, &xconfig); GNUNET_free (config); msize = xc_size + sizeof (struct GNUNET_TESTBED_PeerConfigurationInformationMessage); reply = GNUNET_realloc (xconfig, msize); (void) memmove (&reply[1], reply, xc_size); reply->header.size = htons (msize); reply->header.type = htons (GNUNET_MESSAGE_TYPE_TESTBED_PEERCONFIG); reply->peer_id = msg->peer_id; reply->operation_id = msg->operation_id; GNUNET_TESTING_peer_get_identity (peer_list[peer_id]->details.local.peer, &reply->peer_identity); reply->config_size = htons ((uint16_t) c_size); queue_message (client, &reply->header); GNUNET_SERVER_receive_done (client, GNUNET_OK); } /** * Task for cleaing up overlay connect context structure * * @param cls the overlay connect context * @param tc the task context */ static void occ_cleanup (void *cls, const struct GNUNET_SCHEDULER_TaskContext *tc) { struct OverlayConnectContext *occ = cls; LOG_DEBUG ("Cleaning up occ\n"); GNUNET_free_non_null (occ->emsg); GNUNET_free_non_null (occ->hello); GNUNET_SERVER_client_drop (occ->client); if (NULL != occ->opc) GNUNET_TESTBED_forward_operation_msg_cancel_ (occ->opc); if (GNUNET_SCHEDULER_NO_TASK != occ->send_hello_task) GNUNET_SCHEDULER_cancel (occ->send_hello_task); if (NULL != occ->ch) GNUNET_CORE_disconnect (occ->ch); if (NULL != occ->ghh) GNUNET_TRANSPORT_get_hello_cancel (occ->ghh); if (NULL != occ->p1th) GNUNET_TRANSPORT_disconnect (occ->p1th); if (NULL != occ->p2th) GNUNET_TRANSPORT_disconnect (occ->p2th); GNUNET_free (occ); } /** * Task which will be run when overlay connect request has been timed out * * @param cls the OverlayConnectContext * @param tc the TaskContext */ static void timeout_overlay_connect (void *cls, const struct GNUNET_SCHEDULER_TaskContext *tc) { struct OverlayConnectContext *occ = cls; occ->timeout_task = GNUNET_SCHEDULER_NO_TASK; send_operation_fail_msg (occ->client, occ->op_id, occ->emsg); occ_cleanup (occ, tc); } /** * Function called to notify transport users that another * peer connected to us. * * @param cls closure * @param new_peer the peer that connected * @param ats performance data * @param ats_count number of entries in ats (excluding 0-termination) */ static void overlay_connect_notify (void *cls, const struct GNUNET_PeerIdentity *new_peer, const struct GNUNET_ATS_Information *ats, unsigned int ats_count) { struct OverlayConnectContext *occ = cls; struct GNUNET_TESTBED_ConnectionEventMessage *msg; char *new_peer_str; char *other_peer_str; LOG_DEBUG ("Overlay connect notify\n"); if (0 == memcmp (new_peer, &occ->peer_identity, sizeof (struct GNUNET_PeerIdentity))) return; new_peer_str = GNUNET_strdup (GNUNET_i2s (new_peer)); other_peer_str = GNUNET_strdup (GNUNET_i2s (&occ->other_peer_identity)); if (0 != memcmp (new_peer, &occ->other_peer_identity, sizeof (struct GNUNET_PeerIdentity))) { LOG_DEBUG ("Unexpected peer %4s connected when expecting peer %4s\n", new_peer_str, other_peer_str); GNUNET_free (new_peer_str); GNUNET_free (other_peer_str); return; } GNUNET_free (new_peer_str); LOG_DEBUG ("Peer %4s connected to peer %4s\n", other_peer_str, GNUNET_i2s (&occ->peer_identity)); GNUNET_free (other_peer_str); if (GNUNET_SCHEDULER_NO_TASK != occ->send_hello_task) { GNUNET_SCHEDULER_cancel (occ->send_hello_task); occ->send_hello_task = GNUNET_SCHEDULER_NO_TASK; } GNUNET_assert (GNUNET_SCHEDULER_NO_TASK != occ->timeout_task); GNUNET_SCHEDULER_cancel (occ->timeout_task); occ->timeout_task = GNUNET_SCHEDULER_NO_TASK; GNUNET_free_non_null (occ->emsg); occ->emsg = NULL; if (NULL != occ->p2th) GNUNET_TRANSPORT_disconnect (occ->p2th); occ->p2th = NULL; LOG_DEBUG ("Peers connected - Sending overlay connect success\n"); msg = GNUNET_malloc (sizeof (struct GNUNET_TESTBED_ConnectionEventMessage)); msg->header.size = htons (sizeof (struct GNUNET_TESTBED_ConnectionEventMessage)); msg->header.type = htons (GNUNET_MESSAGE_TYPE_TESTBED_PEERCONEVENT); msg->event_type = htonl (GNUNET_TESTBED_ET_CONNECT); msg->peer1 = htonl (occ->peer_id); msg->peer2 = htonl (occ->other_peer_id); msg->operation_id = GNUNET_htonll (occ->op_id); queue_message (occ->client, &msg->header); GNUNET_SCHEDULER_add_now (&occ_cleanup, occ); } /** * Task to offer HELLO of peer 1 to peer 2 and try to make peer 2 to connect to * peer 1. * * @param cls the OverlayConnectContext * @param tc the TaskContext from scheduler */ static void send_hello (void *cls, const struct GNUNET_SCHEDULER_TaskContext *tc) { struct OverlayConnectContext *occ = cls; char *other_peer_str; occ->send_hello_task = GNUNET_SCHEDULER_NO_TASK; if (0 != (tc->reason & GNUNET_SCHEDULER_REASON_SHUTDOWN)) return; GNUNET_assert (NULL != occ->hello); other_peer_str = GNUNET_strdup (GNUNET_i2s (&occ->other_peer_identity)); if (NULL != occ->peer2_controller) { struct GNUNET_TESTBED_RequestConnectMessage *msg; uint16_t msize; uint16_t hello_size; LOG_DEBUG ("Offering HELLO of %s to %s via Remote Overlay Request\n", GNUNET_i2s (&occ->peer_identity), other_peer_str); hello_size = ntohs (occ->hello->size); msize = sizeof (struct GNUNET_TESTBED_RequestConnectMessage) + hello_size; msg = GNUNET_malloc (msize); msg->header.type = htons (GNUNET_MESSAGE_TYPE_TESTBED_REQUESTCONNECT); msg->header.size = htons (msize); msg->peer = htonl (occ->other_peer_id); msg->operation_id = GNUNET_htonll (occ->op_id); (void) memcpy (&msg->peer_identity, &occ->peer_identity, sizeof (struct GNUNET_PeerIdentity)); memcpy (msg->hello, occ->hello, hello_size); GNUNET_TESTBED_queue_message_ (occ->peer2_controller, &msg->header); } else { LOG_DEBUG ("Offering HELLO of %s to %s\n", GNUNET_i2s (&occ->peer_identity), other_peer_str); GNUNET_TRANSPORT_offer_hello (occ->p2th, occ->hello, NULL, NULL); GNUNET_TRANSPORT_try_connect (occ->p2th, &occ->peer_identity); occ->send_hello_task = GNUNET_SCHEDULER_add_delayed (TRANSPORT_TRY_CONNECT_TIMEOUT, &send_hello, occ); } GNUNET_free (other_peer_str); } /** * Test for checking whether HELLO message is empty * * @param cls empty flag to set * @param address the HELLO * @param expiration expiration of the HELLO * @return */ static int test_address (void *cls, const struct GNUNET_HELLO_Address *address, struct GNUNET_TIME_Absolute expiration) { int *empty = cls; *empty = GNUNET_NO; return GNUNET_OK; } /** * Function called whenever there is an update to the HELLO of peers in the * OverlayConnectClosure. If we have a valid HELLO, we connect to the peer 2's * transport and offer peer 1's HELLO and ask peer 2 to connect to peer 1 * * @param cls closure * @param hello our updated HELLO */ static void hello_update_cb (void *cls, const struct GNUNET_MessageHeader *hello) { struct OverlayConnectContext *occ = cls; int empty; uint16_t msize; msize = ntohs (hello->size); empty = GNUNET_YES; (void) GNUNET_HELLO_iterate_addresses ((const struct GNUNET_HELLO_Message *) hello, GNUNET_NO, &test_address, &empty); if (GNUNET_YES == empty) { LOG_DEBUG ("HELLO of %s is empty\n", GNUNET_i2s (&occ->peer_identity)); return; } LOG_DEBUG ("Received HELLO of %s\n", GNUNET_i2s (&occ->peer_identity)); occ->hello = GNUNET_malloc (msize); memcpy (occ->hello, hello, msize); GNUNET_TRANSPORT_get_hello_cancel (occ->ghh); occ->ghh = NULL; GNUNET_TRANSPORT_disconnect (occ->p1th); occ->p1th = NULL; GNUNET_free_non_null (occ->emsg); if (NULL == occ->peer2_controller) { occ->p2th = GNUNET_TRANSPORT_connect (peer_list[occ->other_peer_id]->details.local.cfg, &occ->other_peer_identity, NULL, NULL, NULL, NULL); if (NULL == occ->p2th) { GNUNET_asprintf (&occ->emsg, "Cannot connect to TRANSPORT of %s\n", GNUNET_i2s (&occ->other_peer_identity)); GNUNET_SCHEDULER_cancel (occ->timeout_task); occ->timeout_task = GNUNET_SCHEDULER_add_now (&timeout_overlay_connect, occ); return; } } occ->emsg = GNUNET_strdup ("Timeout while offering HELLO to other peer"); occ->send_hello_task = GNUNET_SCHEDULER_add_now (&send_hello, occ); } /** * 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...). * * @param cls closure * @param server handle to the server, NULL if we failed * @param my_identity ID of this peer, NULL if we failed */ static void core_startup_cb (void *cls, struct GNUNET_CORE_Handle *server, const struct GNUNET_PeerIdentity *my_identity) { struct OverlayConnectContext *occ = cls; GNUNET_free_non_null (occ->emsg); occ->emsg = GNUNET_strdup ("Failed to connect to CORE\n"); if ((NULL == server) || (NULL == my_identity)) goto error_return; GNUNET_free (occ->emsg); occ->ch = server; occ->emsg = NULL; memcpy (&occ->peer_identity, my_identity, sizeof (struct GNUNET_PeerIdentity)); occ->p1th = GNUNET_TRANSPORT_connect (occ->peer->details.local.cfg, &occ->peer_identity, NULL, NULL, NULL, NULL); if (NULL == occ->p1th) { GNUNET_asprintf (&occ->emsg, "Cannot connect to TRANSPORT of peers %4s", GNUNET_i2s (&occ->peer_identity)); goto error_return; } LOG_DEBUG ("Acquiring HELLO of peer %s\n", GNUNET_i2s (&occ->peer_identity)); occ->emsg = GNUNET_strdup ("Timeout while acquiring HELLO message"); occ->ghh = GNUNET_TRANSPORT_get_hello (occ->p1th, &hello_update_cb, occ); return; error_return: GNUNET_SCHEDULER_cancel (occ->timeout_task); occ->timeout_task = GNUNET_SCHEDULER_add_now (&timeout_overlay_connect, occ); return; } /** * Callback to be called when forwarded get peer config operation as part of * overlay connect is successfull. Connection to Peer 1's core is made and is * checked for new connection from peer 2 * * @param cls ForwardedOperationContext * @param msg the peer create success message */ static void overlay_connect_get_config (void *cls, const struct GNUNET_MessageHeader *msg) { struct OverlayConnectContext *occ = cls; const struct GNUNET_TESTBED_PeerConfigurationInformationMessage *cmsg; const struct GNUNET_CORE_MessageHandler no_handlers[] = { {NULL, 0, 0} }; occ->opc = NULL; if (GNUNET_MESSAGE_TYPE_TESTBED_PEERCONFIG != ntohs (msg->type)) goto error_return; cmsg = (const struct GNUNET_TESTBED_PeerConfigurationInformationMessage *) msg; memcpy (&occ->other_peer_identity, &cmsg->peer_identity, sizeof (struct GNUNET_PeerIdentity)); GNUNET_free_non_null (occ->emsg); occ->emsg = GNUNET_strdup ("Timeout while connecting to CORE"); occ->ch = GNUNET_CORE_connect (occ->peer->details.local.cfg, occ, &core_startup_cb, &overlay_connect_notify, NULL, NULL, GNUNET_NO, NULL, GNUNET_NO, no_handlers); if (NULL == occ->ch) goto error_return; return; error_return: GNUNET_SCHEDULER_cancel (occ->timeout_task); occ->timeout_task = GNUNET_SCHEDULER_add_now (&timeout_overlay_connect, occ); } /** * Handler for GNUNET_MESSAGE_TYPE_TESTBED_OLCONNECT messages * * @param cls NULL * @param client identification of the client * @param message the actual message */ static void handle_overlay_connect (void *cls, struct GNUNET_SERVER_Client *client, const struct GNUNET_MessageHeader *message) { const struct GNUNET_TESTBED_OverlayConnectMessage *msg; struct OverlayConnectContext *occ; const struct GNUNET_CORE_MessageHandler no_handlers[] = { {NULL, 0, 0} }; struct Peer *peer; uint64_t operation_id; uint32_t p1; uint32_t p2; msg = (const struct GNUNET_TESTBED_OverlayConnectMessage *) message; p1 = ntohl (msg->peer1); p2 = ntohl (msg->peer2); GNUNET_assert (p1 < peer_list_size); GNUNET_assert (NULL != peer_list[p1]); peer = peer_list[p1]; operation_id = GNUNET_ntohll (msg->operation_id); if (GNUNET_YES == peer->is_remote) { struct ForwardedOperationContext *fopc; fopc = GNUNET_malloc (sizeof (struct ForwardedOperationContext)); GNUNET_SERVER_client_keep (client); fopc->client = client; fopc->operation_id = operation_id; LOG_DEBUG ("Forwarding overlay connect\n"); fopc->opc = GNUNET_TESTBED_forward_operation_msg_ (peer->details.remote.controller, operation_id, message, &forwarded_operation_reply_relay, fopc); fopc->timeout_task = GNUNET_SCHEDULER_add_delayed (TIMEOUT, &forwarded_operation_timeout, fopc); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } occ = GNUNET_malloc (sizeof (struct OverlayConnectContext)); GNUNET_SERVER_client_keep (client); occ->client = client; occ->peer_id = p1; occ->other_peer_id = p2; occ->peer = peer_list[p1]; occ->op_id = GNUNET_ntohll (msg->operation_id); if ((p2 >= peer_list_size) || (NULL == peer_list[p2])) { uint32_t peer2_host_id; peer2_host_id = ntohl (msg->peer2_host_id); if ((peer2_host_id >= slave_list_size) || (NULL ==slave_list[peer2_host_id])) { GNUNET_break (0); GNUNET_SERVER_client_drop (client); GNUNET_free (occ); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } occ->peer2_controller = slave_list[peer2_host_id]->controller; if (NULL == occ->peer2_controller) { GNUNET_break (0); GNUNET_SERVER_client_drop (client); GNUNET_free (occ); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } } else { if (GNUNET_YES == peer_list[occ->other_peer_id]->is_remote) occ->peer2_controller = peer_list[occ->other_peer_id]->details.remote.controller; } /* Get the identity of the second peer */ if (NULL != occ->peer2_controller) { struct GNUNET_TESTBED_PeerGetConfigurationMessage cmsg; cmsg.header.size = htons (sizeof (struct GNUNET_TESTBED_PeerGetConfigurationMessage)); cmsg.header.type = htons (GNUNET_MESSAGE_TYPE_TESTBED_GETPEERCONFIG); cmsg.peer_id = msg->peer2; cmsg.operation_id = msg->operation_id; occ->opc = GNUNET_TESTBED_forward_operation_msg_ (occ->peer2_controller, occ->op_id, &cmsg.header, &overlay_connect_get_config, occ); occ->emsg = GNUNET_strdup ("Timeout while getting peer identity of peer B\n"); occ->timeout_task = GNUNET_SCHEDULER_add_delayed (GNUNET_TIME_relative_multiply (GNUNET_TIME_UNIT_SECONDS, 30), &timeout_overlay_connect, occ); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } GNUNET_TESTING_peer_get_identity (peer_list[occ->other_peer_id]->details.local.peer, &occ->other_peer_identity); /* Connect to the core of 1st peer and wait for the 2nd peer to connect */ occ->emsg = GNUNET_strdup ("Timeout while connecting to CORE"); occ->ch = GNUNET_CORE_connect (occ->peer->details.local.cfg, occ, &core_startup_cb, &overlay_connect_notify, NULL, NULL, GNUNET_NO, NULL, GNUNET_NO, no_handlers); if (NULL == occ->ch) occ->timeout_task = GNUNET_SCHEDULER_add_now (&timeout_overlay_connect, occ); else occ->timeout_task = GNUNET_SCHEDULER_add_delayed (GNUNET_TIME_relative_multiply (GNUNET_TIME_UNIT_SECONDS, 30), &timeout_overlay_connect, occ); GNUNET_SERVER_receive_done (client, GNUNET_OK); } /** * Function to cleanup RequestOverlayConnectContext and any associated tasks * with it * * @param rocc the RequestOverlayConnectContext */ static void cleanup_rocc (struct RequestOverlayConnectContext *rocc) { if (GNUNET_SCHEDULER_NO_TASK != rocc->attempt_connect_task_id) GNUNET_SCHEDULER_cancel (rocc->attempt_connect_task_id); if (GNUNET_SCHEDULER_NO_TASK != rocc->timeout_rocc_task_id) GNUNET_SCHEDULER_cancel (rocc->timeout_rocc_task_id); GNUNET_TRANSPORT_disconnect (rocc->th); GNUNET_free_non_null (rocc->hello); GNUNET_free (rocc); } /** * Task to timeout rocc and cleanit up * * @param cls the RequestOverlayConnectContext * @param tc the TaskContext from scheduler */ static void timeout_rocc_task (void *cls, const struct GNUNET_SCHEDULER_TaskContext *tc) { struct RequestOverlayConnectContext *rocc = cls; rocc->timeout_rocc_task_id = GNUNET_SCHEDULER_NO_TASK; cleanup_rocc (rocc); } /** * Function called to notify transport users that another * peer connected to us. * * @param cls closure * @param new_peer the peer that connected * @param ats performance data * @param ats_count number of entries in ats (excluding 0-termination) */ static void transport_connect_notify (void *cls, const struct GNUNET_PeerIdentity *new_peer, const struct GNUNET_ATS_Information * ats, uint32_t ats_count) { struct RequestOverlayConnectContext *rocc = cls; LOG_DEBUG ("Request Overlay connect notify\n"); if (0 != memcmp (new_peer, &rocc->a_id, sizeof (struct GNUNET_PeerIdentity))) return; LOG_DEBUG ("Peer %4s connected\n", GNUNET_i2s (&rocc->a_id)); cleanup_rocc (rocc); } /** * Task to offer the HELLO message to the peer and ask it to connect to the peer * whose identity is in RequestOverlayConnectContext * * @param cls the RequestOverlayConnectContext * @param tc the TaskContext from scheduler */ static void attempt_connect_task (void *cls, const struct GNUNET_SCHEDULER_TaskContext *tc) { struct RequestOverlayConnectContext *rocc = cls; rocc->attempt_connect_task_id = GNUNET_SCHEDULER_NO_TASK; GNUNET_TRANSPORT_offer_hello (rocc->th, rocc->hello, NULL, NULL); GNUNET_TRANSPORT_try_connect (rocc->th, &rocc->a_id); rocc->attempt_connect_task_id = GNUNET_SCHEDULER_add_delayed (TRANSPORT_TRY_CONNECT_TIMEOUT, &attempt_connect_task, rocc); } /** * Handler for GNUNET_MESSAGE_TYPE_TESTBED_REQUESTCONNECT messages * * @param cls NULL * @param client identification of the client * @param message the actual message */ static void handle_overlay_request_connect (void *cls, struct GNUNET_SERVER_Client *client, const struct GNUNET_MessageHeader *message) { const struct GNUNET_TESTBED_RequestConnectMessage *msg; struct RequestOverlayConnectContext *rocc; struct Peer *peer; uint32_t peer_id; uint16_t msize; uint16_t hsize; msize = ntohs (message->size); if (sizeof (struct GNUNET_TESTBED_RequestConnectMessage) >= msize) { GNUNET_break (0); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } msg = (const struct GNUNET_TESTBED_RequestConnectMessage *) message; if ((NULL == msg->hello) || (GNUNET_MESSAGE_TYPE_HELLO != ntohs (msg->hello->type))) { GNUNET_break (0); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } hsize = ntohs (msg->hello->size); if ((sizeof (struct GNUNET_TESTBED_RequestConnectMessage) + hsize) != msize) { GNUNET_break (0); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } peer_id = ntohl (msg->peer); if ((peer_id >= peer_list_size) || (NULL == (peer = peer_list[peer_id]))) { GNUNET_break_op (0); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } if (GNUNET_NO != peer->is_remote) { GNUNET_break (0); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } rocc = GNUNET_malloc (sizeof (struct RequestOverlayConnectContext)); rocc->th = GNUNET_TRANSPORT_connect (peer->details.local.cfg, NULL, rocc, NULL, &transport_connect_notify, NULL); if (NULL == rocc->th) { GNUNET_break (0); GNUNET_free (rocc); GNUNET_SERVER_receive_done (client, GNUNET_SYSERR); return; } memcpy (&rocc->a_id, &msg->peer_identity, sizeof (struct GNUNET_PeerIdentity)); rocc->hello = GNUNET_malloc (hsize); memcpy (rocc->hello, msg->hello, hsize); /* GNUNET_TRANSPORT_offer_hello (th, msg->hello, NULL, NULL); */ /* GNUNET_TRANSPORT_try_connect (th, &msg->peer_identity); */ rocc->attempt_connect_task_id = GNUNET_SCHEDULER_add_now (&attempt_connect_task, rocc); rocc->timeout_rocc_task_id = GNUNET_SCHEDULER_add_delayed (TIMEOUT, &timeout_rocc_task, rocc); GNUNET_SERVER_receive_done (client, GNUNET_OK); } /** * Handler for GNUNET_MESSAGE_TYPE_TESTBED_GETSLAVECONFIG messages * * @param cls NULL * @param client identification of the client * @param message the actual message */ static void handle_slave_get_config (void *cls, struct GNUNET_SERVER_Client *client, const struct GNUNET_MessageHeader *message) { struct GNUNET_TESTBED_SlaveGetConfigurationMessage *msg; struct Slave *slave; struct GNUNET_TESTBED_SlaveConfiguration *reply; char *config; char *xconfig; size_t config_size; size_t xconfig_size; size_t reply_size; uint64_t op_id; uint32_t slave_id; msg = (struct GNUNET_TESTBED_SlaveGetConfigurationMessage *) message; slave_id = ntohl (msg->slave_id); op_id = GNUNET_ntohll (msg->operation_id); if ((slave_list_size <= slave_id) || (NULL == slave_list[slave_id])) { send_operation_fail_msg (client, op_id, "Slave not found"); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } slave = slave_list[slave_id]; if (NULL == slave->cfg) { send_operation_fail_msg (client, op_id, "Configuration not found (slave not started by me)"); GNUNET_SERVER_receive_done (client, GNUNET_OK); return; } config = GNUNET_CONFIGURATION_serialize (slave->cfg, &config_size); xconfig_size = GNUNET_TESTBED_compress_config_ (config, config_size, &xconfig); GNUNET_free (config); reply_size = xconfig_size + sizeof (struct GNUNET_TESTBED_SlaveConfiguration); GNUNET_break (reply_size <= UINT16_MAX); GNUNET_break (config_size <= UINT16_MAX); reply = GNUNET_realloc (xconfig, reply_size); (void) memmove (&reply[1], reply, xconfig_size); reply->header.type = htons (GNUNET_MESSAGE_TYPE_TESTBED_SLAVECONFIG); reply->header.size = htons ((uint16_t) reply_size); reply->slave_id = msg->slave_id; reply->operation_id = msg->operation_id; reply->config_size = htons ((uint16_t) config_size); queue_message (client, &reply->header); GNUNET_SERVER_receive_done (client, GNUNET_OK); } /** * Iterator over hash map entries. * * @param cls closure * @param key current key code * @param value value in the hash map * @return GNUNET_YES if we should continue to * iterate, * GNUNET_NO if not. */ static int ss_map_free_iterator (void *cls, const struct GNUNET_HashCode *key, void *value) { struct SharedService *ss = value; GNUNET_assert (GNUNET_YES == GNUNET_CONTAINER_multihashmap_remove (ss_map, key, value)); GNUNET_free (ss->name); GNUNET_free (ss); return GNUNET_YES; } /** * Task to clean up and shutdown nicely * * @param cls NULL * @param tc the TaskContext from scheduler */ static void shutdown_task (void *cls, const struct GNUNET_SCHEDULER_TaskContext *tc) { struct LCFContextQueue *lcfq; uint32_t id; shutdown_task_id = GNUNET_SCHEDULER_NO_TASK; LOG (GNUNET_ERROR_TYPE_DEBUG, "Shutting down testbed service\n"); (void) GNUNET_CONTAINER_multihashmap_iterate (ss_map, &ss_map_free_iterator, NULL); GNUNET_CONTAINER_multihashmap_destroy (ss_map); if (NULL != lcfq_head) { if (GNUNET_SCHEDULER_NO_TASK != lcf_proc_task_id) { GNUNET_SCHEDULER_cancel (lcf_proc_task_id); lcf_proc_task_id = GNUNET_SCHEDULER_NO_TASK; } if (NULL != lcfq_head->lcf->rhandle) GNUNET_TESTBED_cancel_registration (lcfq_head->lcf->rhandle); } GNUNET_assert (GNUNET_SCHEDULER_NO_TASK == lcf_proc_task_id); for (lcfq = lcfq_head; NULL != lcfq; lcfq = lcfq_head) { GNUNET_free (lcfq->lcf->msg); GNUNET_free (lcfq->lcf); GNUNET_CONTAINER_DLL_remove (lcfq_head, lcfq_tail, lcfq); GNUNET_free (lcfq); } /* Clear peer list */ for (id = 0; id < peer_list_size; id++) if (NULL != peer_list[id]) { if (GNUNET_NO == peer_list[id]->is_remote) { if (GNUNET_YES == peer_list[id]->details.local.is_running) GNUNET_TESTING_peer_stop (peer_list[id]->details.local.peer); GNUNET_TESTING_peer_destroy (peer_list[id]->details.local.peer); GNUNET_CONFIGURATION_destroy (peer_list[id]->details.local.cfg); } GNUNET_free (peer_list[id]); } GNUNET_free_non_null (peer_list); /* Clear host list */ for (id = 0; id < host_list_size; id++) if (NULL != host_list[id]) GNUNET_TESTBED_host_destroy (host_list[id]); GNUNET_free_non_null (host_list); /* Clear route list */ for (id = 0; id < route_list_size; id++) if (NULL != route_list[id]) GNUNET_free (route_list[id]); GNUNET_free_non_null (route_list); /* Clear slave_list */ for (id = 0; id < slave_list_size; id++) if (NULL != slave_list[id]) { if (NULL != slave_list[id]->cfg) GNUNET_CONFIGURATION_destroy (slave_list[id]->cfg); if (NULL != slave_list[id]->controller) GNUNET_TESTBED_controller_disconnect (slave_list[id]->controller); if (NULL != slave_list[id]->controller_proc) GNUNET_TESTBED_controller_stop (slave_list[id]->controller_proc); GNUNET_free (slave_list[id]); } GNUNET_free_non_null (slave_list); if (NULL != master_context) { GNUNET_free_non_null (master_context->master_ip); if (NULL != master_context->system) GNUNET_TESTING_system_destroy (master_context->system, GNUNET_YES); GNUNET_free (master_context); master_context = NULL; } } /** * Callback for client disconnect * * @param cls NULL * @param client the client which has disconnected */ static void client_disconnect_cb (void *cls, struct GNUNET_SERVER_Client *client) { if (NULL == master_context) return; if (client == master_context->client) { LOG (GNUNET_ERROR_TYPE_DEBUG, "Master client disconnected\n"); GNUNET_SERVER_client_drop (client); /* should not be needed as we're terminated by failure to read * from stdin, but if stdin fails for some reason, this shouldn't * hurt for now --- might need to revise this later if we ever * decide that master connections might be temporarily down * for some reason */ //GNUNET_SCHEDULER_shutdown (); } } /** * Testbed setup * * @param cls closure * @param server the initialized server * @param cfg configuration to use */ static void testbed_run (void *cls, struct GNUNET_SERVER_Handle *server, const struct GNUNET_CONFIGURATION_Handle *cfg) { static const struct GNUNET_SERVER_MessageHandler message_handlers[] = { {&handle_init, NULL, GNUNET_MESSAGE_TYPE_TESTBED_INIT, 0}, {&handle_add_host, NULL, GNUNET_MESSAGE_TYPE_TESTBED_ADDHOST, 0}, {&handle_configure_shared_service, NULL, GNUNET_MESSAGE_TYPE_TESTBED_SERVICESHARE, 0}, {&handle_link_controllers, NULL, GNUNET_MESSAGE_TYPE_TESTBED_LCONTROLLERS, 0}, {&handle_peer_create, NULL, GNUNET_MESSAGE_TYPE_TESTBED_CREATEPEER, 0}, {&handle_peer_destroy, NULL, GNUNET_MESSAGE_TYPE_TESTBED_DESTROYPEER, sizeof (struct GNUNET_TESTBED_PeerDestroyMessage)}, {&handle_peer_start, NULL, GNUNET_MESSAGE_TYPE_TESTBED_STARTPEER, sizeof (struct GNUNET_TESTBED_PeerStartMessage)}, {&handle_peer_stop, NULL, GNUNET_MESSAGE_TYPE_TESTBED_STOPPEER, sizeof (struct GNUNET_TESTBED_PeerStopMessage)}, {&handle_peer_get_config, NULL, GNUNET_MESSAGE_TYPE_TESTBED_GETPEERCONFIG, sizeof (struct GNUNET_TESTBED_PeerGetConfigurationMessage)}, {&handle_overlay_connect, NULL, GNUNET_MESSAGE_TYPE_TESTBED_OLCONNECT, sizeof (struct GNUNET_TESTBED_OverlayConnectMessage)}, {&handle_overlay_request_connect, NULL, GNUNET_MESSAGE_TYPE_TESTBED_REQUESTCONNECT, 0}, {handle_slave_get_config, NULL, GNUNET_MESSAGE_TYPE_TESTBED_GETSLAVECONFIG, sizeof (struct GNUNET_TESTBED_SlaveGetConfigurationMessage)}, {NULL} }; GNUNET_SERVER_add_handlers (server, message_handlers); GNUNET_SERVER_disconnect_notify (server, &client_disconnect_cb, NULL); ss_map = GNUNET_CONTAINER_multihashmap_create (5); shutdown_task_id = GNUNET_SCHEDULER_add_delayed (GNUNET_TIME_UNIT_FOREVER_REL, &shutdown_task, NULL); LOG_DEBUG ("Testbed startup complete\n"); } /** * The starting point of execution */ int main (int argc, char *const *argv) { //sleep (15); /* Debugging */ return (GNUNET_OK == GNUNET_SERVICE_run (argc, argv, "testbed", GNUNET_SERVICE_OPTION_NONE, &testbed_run, NULL)) ? 0 : 1; } /* end of gnunet-service-testbed.c */