/* DHT.c * * An implementation of the DHT as seen in docs/DHT.txt * Copyright (C) 2013 Tox project All Rights Reserved. This file is part of Tox. Tox 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 3 of the License, or (at your option) any later version. Tox 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 Tox. If not, see . */ #include "DHT.h" typedef struct { uint8_t client_id[CLIENT_ID_SIZE]; IP_Port ip_port; uint32_t timestamp; uint32_t last_pinged; }Client_data; //maximum number of clients stored per friend. #define MAX_FRIEND_CLIENTS 8 typedef struct { uint8_t client_id[CLIENT_ID_SIZE]; Client_data client_list[MAX_FRIEND_CLIENTS]; uint32_t lastgetnode;//time at which the last get_nodes request was sent. }Friend; typedef struct { uint8_t client_id[CLIENT_ID_SIZE]; IP_Port ip_port; }Node_format; typedef struct { IP_Port ip_port; uint64_t ping_id; uint32_t timestamp; }Pinged; //Our client id/public key uint8_t self_public_key[CLIENT_ID_SIZE]; uint8_t self_secret_key[crypto_box_SECRETKEYBYTES]; //TODO: Move these out of here and put them into the .c file. //A list of the clients mathematically closest to ours. #define LCLIENT_LIST 32 static Client_data close_clientlist[LCLIENT_LIST]; static Friend * friends_list; static uint16_t num_friends; //The list of ip ports along with the ping_id of what we sent them and a timestamp #define LPING_ARRAY 128 static Pinged pings[LPING_ARRAY]; #define LSEND_NODES_ARRAY LPING_ARRAY/2 static Pinged send_nodes[LSEND_NODES_ARRAY]; //Compares client_id1 and client_id2 with client_id //return 0 if both are same distance //return 1 if client_id1 is closer. //return 2 if client_id2 is closer. int id_closest(uint8_t * client_id, uint8_t * client_id1, uint8_t * client_id2)//tested { uint32_t i; for(i = 0; i < CLIENT_ID_SIZE; i++) { if(abs(client_id[i] ^ client_id1[i]) < abs(client_id[i] ^ client_id2[i])) { return 1; } else if(abs(client_id[i] ^ client_id1[i]) > abs(client_id[i] ^ client_id2[i])) { return 2; } } return 0; } //check if client with client_id is already in list of length length. //if it is set it's corresponding timestamp to current time. //if the id is already in the list with a different ip_port, update it. //return True(1) or False(0) //TODO: maybe optimize this. int client_in_list(Client_data * list, uint32_t length, uint8_t * client_id, IP_Port ip_port) { uint32_t i; uint32_t temp_time = unix_time(); for(i = 0; i < length; i++) { if(memcmp(list[i].client_id, client_id, CLIENT_ID_SIZE) == 0) { //Refresh the client timestamp. list[i].timestamp = temp_time; list[i].ip_port.ip.i = ip_port.ip.i; list[i].ip_port.port = ip_port.port; return 1; } } return 0; } //check if client with client_id is already in node format list of length length. //return True(1) or False(0) int client_in_nodelist(Node_format * list, uint32_t length, uint8_t * client_id) { uint32_t i; for(i = 0; i < length; i++) { if(memcmp(list[i].client_id, client_id, CLIENT_ID_SIZE) == 0) { return 1; } } return 0; } //the number of seconds for a non responsive node to become bad. #define BAD_NODE_TIMEOUT 130 //The max number of nodes to send with send nodes. #define MAX_SENT_NODES 8 //Find MAX_SENT_NODES nodes closest to the client_id for the send nodes request: //put them in the nodes_list and return how many were found. //TODO: Make this function much more efficient. int get_close_nodes(uint8_t * client_id, Node_format * nodes_list) { uint32_t i, j, k; int num_nodes=0; uint32_t temp_time = unix_time(); for(i = 0; i < LCLIENT_LIST; i++) { if(close_clientlist[i].timestamp + BAD_NODE_TIMEOUT > temp_time && !client_in_nodelist(nodes_list, MAX_SENT_NODES,close_clientlist[i].client_id)) //if node is good and not already in list. { if(num_nodes < MAX_SENT_NODES) { memcpy(nodes_list[num_nodes].client_id, close_clientlist[i].client_id, CLIENT_ID_SIZE); nodes_list[num_nodes].ip_port = close_clientlist[i].ip_port; num_nodes++; } else for(j = 0; j < MAX_SENT_NODES; j++) { if(id_closest(client_id, nodes_list[j].client_id, close_clientlist[i].client_id) == 2) { memcpy(nodes_list[j].client_id, close_clientlist[i].client_id, CLIENT_ID_SIZE); nodes_list[j].ip_port = close_clientlist[i].ip_port; break; } } } } for(i = 0; i < num_friends; i++) { for(j = 0; j < MAX_FRIEND_CLIENTS; j++) { if(friends_list[i].client_list[j].timestamp + BAD_NODE_TIMEOUT > temp_time && !client_in_nodelist(nodes_list, MAX_SENT_NODES,friends_list[i].client_list[j].client_id)) //if node is good and not already in list. { if(num_nodes < MAX_SENT_NODES) { memcpy(nodes_list[num_nodes].client_id, friends_list[i].client_list[j].client_id, CLIENT_ID_SIZE); nodes_list[num_nodes].ip_port = friends_list[i].client_list[j].ip_port; num_nodes++; } else for(k = 0; k < MAX_SENT_NODES; k++) { if(id_closest(client_id, nodes_list[k].client_id, friends_list[i].client_list[j].client_id) == 2) { memcpy(nodes_list[k].client_id, friends_list[i].client_list[j].client_id, CLIENT_ID_SIZE); nodes_list[k].ip_port = friends_list[i].client_list[j].ip_port; break; } } } } } return num_nodes; } //replace first bad (or empty) node with this one //return 0 if successful //return 1 if not (list contains no bad nodes) int replace_bad(Client_data * list, uint32_t length, uint8_t * client_id, IP_Port ip_port)//tested { uint32_t i; uint32_t temp_time = unix_time(); for(i = 0; i < length; i++) { if(list[i].timestamp + BAD_NODE_TIMEOUT < temp_time)//if node is bad. { memcpy(list[i].client_id, client_id, CLIENT_ID_SIZE); list[i].ip_port = ip_port; list[i].timestamp = temp_time; return 0; } } return 1; } //replace the first good node that is further to the comp_client_id than that of the client_id in the list int replace_good(Client_data * list, uint32_t length, uint8_t * client_id, IP_Port ip_port, uint8_t * comp_client_id) { uint32_t i; uint32_t temp_time = unix_time(); for(i = 0; i < length; i++) { if(id_closest(comp_client_id, list[i].client_id, client_id) == 2) { memcpy(list[i].client_id, client_id, CLIENT_ID_SIZE); list[i].ip_port = ip_port; list[i].timestamp = temp_time; return 0; } } return 1; } //Attempt to add client with ip_port and client_id to the friends client list and close_clientlist void addto_lists(IP_Port ip_port, uint8_t * client_id) { uint32_t i; //NOTE: current behavior if there are two clients with the same id is to replace the first ip by the second. if(!client_in_list(close_clientlist, LCLIENT_LIST, client_id, ip_port)) { if(replace_bad(close_clientlist, LCLIENT_LIST, client_id, ip_port)) { //if we can't replace bad nodes we try replacing good ones replace_good(close_clientlist, LCLIENT_LIST, client_id, ip_port, self_public_key); } } for(i = 0; i < num_friends; i++) { if(!client_in_list(friends_list[i].client_list, MAX_FRIEND_CLIENTS, client_id, ip_port)) { if(replace_bad(friends_list[i].client_list, MAX_FRIEND_CLIENTS, client_id, ip_port)) { //if we can't replace bad nodes we try replacing good ones replace_good(friends_list[i].client_list, MAX_FRIEND_CLIENTS, client_id, ip_port, self_public_key); } } } } //ping timeout in seconds #define PING_TIMEOUT 5 //check if we are currently pinging an ip_port and/or a ping_id //Variables with values of zero will not be checked. //if we are already, return 1 //else return 0 //TODO: Maybe optimize this int is_pinging(IP_Port ip_port, uint64_t ping_id) { uint32_t i; uint8_t pinging; uint32_t temp_time = unix_time(); for(i = 0; i < LPING_ARRAY; i++ ) { if((pings[i].timestamp + PING_TIMEOUT) > temp_time) { pinging = 0; if(ip_port.ip.i != 0) { if(pings[i].ip_port.ip.i == ip_port.ip.i && pings[i].ip_port.port == ip_port.port) { pinging++; } } if(ping_id != 0) { if(pings[i].ping_id == ping_id) { pinging++; } } if(pinging == (ping_id != 0) + (ip_port.ip.i != 0)) { return 1; } } } return 0; } //Same as last function but for get_node requests. int is_gettingnodes(IP_Port ip_port, uint64_t ping_id) { uint32_t i; uint8_t pinging; uint32_t temp_time = unix_time(); for(i = 0; i < LSEND_NODES_ARRAY; i++ ) { if((send_nodes[i].timestamp + PING_TIMEOUT) > temp_time) { pinging = 0; if(ip_port.ip.i != 0) { if(send_nodes[i].ip_port.ip.i == ip_port.ip.i && send_nodes[i].ip_port.port == ip_port.port) { pinging++; } } if(ping_id != 0) { if(send_nodes[i].ping_id == ping_id) { pinging++; } } if(pinging == (ping_id != 0) + (ip_port.ip.i != 0)) { return 1; } } } return 0; } //Add a new ping request to the list of ping requests //returns the ping_id to put in the ping request //returns 0 if problem. //TODO: Maybe optimize this uint64_t add_pinging(IP_Port ip_port) { uint32_t i, j; uint64_t ping_id = ((uint64_t)random_int() << 32) + random_int(); uint32_t temp_time = unix_time(); for(i = 0; i < PING_TIMEOUT; i++ ) { for(j = 0; j < LPING_ARRAY; j++ ) { if((pings[j].timestamp + PING_TIMEOUT - i) < temp_time) { pings[j].timestamp = temp_time; pings[j].ip_port = ip_port; pings[j].ping_id = ping_id; return ping_id; } } } return 0; } //Same but for get node requests uint64_t add_gettingnodes(IP_Port ip_port) { uint32_t i, j; uint64_t ping_id = ((uint64_t)random_int() << 32) + random_int(); uint32_t temp_time = unix_time(); for(i = 0; i < PING_TIMEOUT; i++ ) { for(j = 0; j < LSEND_NODES_ARRAY; j++ ) { if((send_nodes[j].timestamp + PING_TIMEOUT - i) < temp_time) { send_nodes[j].timestamp = temp_time; send_nodes[j].ip_port = ip_port; send_nodes[j].ping_id = ping_id; return ping_id; } } } return 0; } //send a ping request //Ping request only works if none has been sent to that ip/port in the last 5 seconds. static int pingreq(IP_Port ip_port, uint8_t * public_key) { if(memcmp(public_key, self_public_key, CLIENT_ID_SIZE) == 0)//check if packet is gonna be sent to ourself { return 1; } if(is_pinging(ip_port, 0)) { return 1; } uint64_t ping_id = add_pinging(ip_port); if(ping_id == 0) { return 1; } uint8_t data[1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES + sizeof(ping_id) + ENCRYPTION_PADDING]; uint8_t encrypt[sizeof(ping_id) + ENCRYPTION_PADDING]; uint8_t nonce[crypto_box_NONCEBYTES]; random_nonce(nonce); int len = encrypt_data(public_key, self_secret_key, nonce, (uint8_t *)&ping_id, sizeof(ping_id), encrypt); if(len != sizeof(ping_id) + ENCRYPTION_PADDING) { return -1; } data[0] = 0; memcpy(data + 1, self_public_key, CLIENT_ID_SIZE); memcpy(data + 1 + CLIENT_ID_SIZE, nonce, crypto_box_NONCEBYTES); memcpy(data + 1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES, encrypt, len); return sendpacket(ip_port, data, sizeof(data)); } //send a ping response static int pingres(IP_Port ip_port, uint8_t * public_key, uint64_t ping_id) { if(memcmp(public_key, self_public_key, CLIENT_ID_SIZE) == 0)//check if packet is gonna be sent to ourself { return 1; } uint8_t data[1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES + sizeof(ping_id) + ENCRYPTION_PADDING]; uint8_t encrypt[sizeof(ping_id) + ENCRYPTION_PADDING]; uint8_t nonce[crypto_box_NONCEBYTES]; random_nonce(nonce); int len = encrypt_data(public_key, self_secret_key, nonce, (uint8_t *)&ping_id, sizeof(ping_id), encrypt); if(len != sizeof(ping_id) + ENCRYPTION_PADDING) { return -1; } data[0] = 1; memcpy(data + 1, self_public_key, CLIENT_ID_SIZE); memcpy(data + 1 + CLIENT_ID_SIZE, nonce, crypto_box_NONCEBYTES); memcpy(data + 1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES, encrypt, len); return sendpacket(ip_port, data, sizeof(data)); } //send a getnodes request static int getnodes(IP_Port ip_port, uint8_t * public_key, uint8_t * client_id) { if(memcmp(public_key, self_public_key, CLIENT_ID_SIZE) == 0)//check if packet is gonna be sent to ourself { return 1; } if(is_gettingnodes(ip_port, 0)) { return 1; } uint64_t ping_id = add_gettingnodes(ip_port); if(ping_id == 0) { return 1; } uint8_t data[1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES + sizeof(ping_id) + CLIENT_ID_SIZE + ENCRYPTION_PADDING]; uint8_t plain[sizeof(ping_id) + CLIENT_ID_SIZE]; uint8_t encrypt[sizeof(ping_id) + CLIENT_ID_SIZE + ENCRYPTION_PADDING]; uint8_t nonce[crypto_box_NONCEBYTES]; random_nonce(nonce); memcpy(plain, &ping_id, sizeof(ping_id)); memcpy(plain + sizeof(ping_id), client_id, CLIENT_ID_SIZE); int len = encrypt_data(public_key, self_secret_key, nonce, plain, sizeof(ping_id) + CLIENT_ID_SIZE, encrypt); if(len != sizeof(ping_id) + CLIENT_ID_SIZE + ENCRYPTION_PADDING) { return -1; } data[0] = 2; memcpy(data + 1, self_public_key, CLIENT_ID_SIZE); memcpy(data + 1 + CLIENT_ID_SIZE, nonce, crypto_box_NONCEBYTES); memcpy(data + 1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES, encrypt, len); return sendpacket(ip_port, data, sizeof(data)); } //send a send nodes response static int sendnodes(IP_Port ip_port, uint8_t * public_key, uint8_t * client_id, uint64_t ping_id) { if(memcmp(public_key, self_public_key, CLIENT_ID_SIZE) == 0)//check if packet is gonna be sent to ourself { return 1; } uint8_t data[1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES + sizeof(ping_id) + sizeof(Node_format) * MAX_SENT_NODES + ENCRYPTION_PADDING]; Node_format nodes_list[MAX_SENT_NODES]; int num_nodes = get_close_nodes(client_id, nodes_list); if(num_nodes == 0) { return 0; } uint8_t plain[sizeof(ping_id) + sizeof(Node_format) * MAX_SENT_NODES]; uint8_t encrypt[sizeof(ping_id) + sizeof(Node_format) * MAX_SENT_NODES + ENCRYPTION_PADDING]; uint8_t nonce[crypto_box_NONCEBYTES]; random_nonce(nonce); memcpy(plain, &ping_id, sizeof(ping_id)); memcpy(plain + sizeof(ping_id), nodes_list, num_nodes * sizeof(Node_format)); int len = encrypt_data(public_key, self_secret_key, nonce, plain, sizeof(ping_id) + num_nodes * sizeof(Node_format), encrypt); if(len != sizeof(ping_id) + num_nodes * sizeof(Node_format) + ENCRYPTION_PADDING) { return -1; } data[0] = 3; memcpy(data + 1, self_public_key, CLIENT_ID_SIZE); memcpy(data + 1 + CLIENT_ID_SIZE, nonce, crypto_box_NONCEBYTES); memcpy(data + 1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES, encrypt, len); return sendpacket(ip_port, data, 1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES + len); } //Packet handling functions //One to handle each types of packets we receive //return 0 if handled correctly, 1 if packet is bad. int handle_pingreq(uint8_t * packet, uint32_t length, IP_Port source) { uint64_t ping_id; if(length != 1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES + sizeof(ping_id) + ENCRYPTION_PADDING) { return 1; } if(memcmp(packet + 1, self_public_key, CLIENT_ID_SIZE) == 0)//check if packet is from ourself. { return 1; } int len = decrypt_data(packet + 1, self_secret_key, packet + 1 + CLIENT_ID_SIZE, packet + 1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES, sizeof(ping_id) + ENCRYPTION_PADDING, (uint8_t *)&ping_id); if(len != sizeof(ping_id)) { return 1; } pingres(source, packet + 1, ping_id); pingreq(source, packet + 1);//TODO: make this smarter? return 0; } int handle_pingres(uint8_t * packet, uint32_t length, IP_Port source) { uint64_t ping_id; if(length != 1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES + sizeof(ping_id) + ENCRYPTION_PADDING) { return 1; } if(memcmp(packet + 1, self_public_key, CLIENT_ID_SIZE) == 0)//check if packet is from ourself. { return 1; } int len = decrypt_data(packet + 1, self_secret_key, packet + 1 + CLIENT_ID_SIZE, packet + 1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES, sizeof(ping_id) + ENCRYPTION_PADDING, (uint8_t *)&ping_id); if(len != sizeof(ping_id)) { return 1; } if(is_pinging(source, ping_id)) { addto_lists(source, packet + 1); return 0; } return 1; } int handle_getnodes(uint8_t * packet, uint32_t length, IP_Port source) { uint64_t ping_id; if(length != 1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES + sizeof(ping_id) + CLIENT_ID_SIZE + ENCRYPTION_PADDING) { return 1; } if(memcmp(packet + 1, self_public_key, CLIENT_ID_SIZE) == 0)//check if packet is from ourself. { return 1; } uint8_t plain[sizeof(ping_id) + CLIENT_ID_SIZE]; int len = decrypt_data(packet + 1, self_secret_key, packet + 1 + CLIENT_ID_SIZE, packet + 1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES, sizeof(ping_id) + CLIENT_ID_SIZE + ENCRYPTION_PADDING, plain); if(len != sizeof(ping_id) + CLIENT_ID_SIZE) { return 1; } memcpy(&ping_id, plain, sizeof(ping_id)); sendnodes(source, packet + 1, plain + sizeof(ping_id), ping_id); pingreq(source, packet + 1);//TODO: make this smarter? return 0; } int handle_sendnodes(uint8_t * packet, uint32_t length, IP_Port source) { uint64_t ping_id; if(length > (1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES + sizeof(ping_id) + sizeof(Node_format) * MAX_SENT_NODES + ENCRYPTION_PADDING) || (length - (1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES + sizeof(ping_id) + ENCRYPTION_PADDING)) % (sizeof(Node_format)) != 0 || length < 1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES + sizeof(ping_id) + sizeof(Node_format) + ENCRYPTION_PADDING) { return 1; } uint32_t num_nodes = (length - (1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES + sizeof(ping_id) + ENCRYPTION_PADDING)) / sizeof(Node_format); uint8_t plain[sizeof(ping_id) + sizeof(Node_format) * MAX_SENT_NODES]; int len = decrypt_data(packet + 1, self_secret_key, packet + 1 + CLIENT_ID_SIZE, packet + 1 + CLIENT_ID_SIZE + crypto_box_NONCEBYTES, sizeof(ping_id) + num_nodes * sizeof(Node_format) + ENCRYPTION_PADDING, plain); if(len != sizeof(ping_id) + num_nodes * sizeof(Node_format)) { return 1; } memcpy(&ping_id, plain, sizeof(ping_id)); if(!is_gettingnodes(source, ping_id)) { return 1; } Node_format nodes_list[MAX_SENT_NODES]; memcpy(nodes_list, plain + sizeof(ping_id), num_nodes * sizeof(Node_format)); uint32_t i; for(i = 0; i < num_nodes; i++) { pingreq(nodes_list[i].ip_port, nodes_list[i].client_id); } addto_lists(source, packet + 1); return 0; } //END of packet handling functions int DHT_addfriend(uint8_t * client_id) { Friend * temp; if(num_friends == 0) { temp = malloc(sizeof(Friend)); } else { temp = realloc(friends_list, sizeof(Friend) * (num_friends + 1)); } if(temp == NULL) { return 1; } friends_list = temp; memset(&friends_list[num_friends], 0, sizeof(Friend)); memcpy(friends_list[num_friends].client_id, client_id, CLIENT_ID_SIZE); num_friends++; return 0; } int DHT_delfriend(uint8_t * client_id) { uint32_t i; Friend * temp; for(i = 0; i < num_friends; i++) { if(memcmp(friends_list[i].client_id, client_id, CLIENT_ID_SIZE) == 0)//Equal { num_friends--; if(num_friends != i) { memcpy(friends_list[i].client_id, friends_list[num_friends].client_id, CLIENT_ID_SIZE); } temp = realloc(friends_list, sizeof(friends_list) * (num_friends)); if(temp != NULL) { friends_list = temp; } return 0; } } return 1; } //TODO: Optimize this. IP_Port DHT_getfriendip(uint8_t * client_id) { uint32_t i, j; IP_Port empty = {{{0}}, 0}; uint32_t temp_time = unix_time(); for(i = 0; i < num_friends; i++) { if(memcmp(friends_list[i].client_id, client_id, CLIENT_ID_SIZE) == 0)//Equal { for(j = 0; j < MAX_FRIEND_CLIENTS; j++) { if(memcmp(friends_list[i].client_list[j].client_id, client_id, CLIENT_ID_SIZE) == 0 && friends_list[i].client_list[j].timestamp + BAD_NODE_TIMEOUT > temp_time) { return friends_list[i].client_list[j].ip_port; } } return empty; } } empty.ip.i = 1; return empty; } int DHT_handlepacket(uint8_t * packet, uint32_t length, IP_Port source) { switch (packet[0]) { case 0: return handle_pingreq(packet, length, source); case 1: return handle_pingres(packet, length, source); case 2: return handle_getnodes(packet, length, source); case 3: return handle_sendnodes(packet, length, source); default: return 1; } return 0; } //The timeout after which a node is discarded completely. #define Kill_NODE_TIMEOUT 300 //ping interval in seconds for each node in our lists. #define PING_INTERVAL 60 //ping interval in seconds for each random sending of a get nodes request. #define GET_NODE_INTERVAL 10 //Ping each client in the "friends" list every 60 seconds. //Send a get nodes request every 20 seconds to a random good node for each "friend" in our "friends" list. void doDHTFriends() { uint32_t i, j; uint32_t temp_time = unix_time(); uint32_t num_nodes = 0; uint32_t rand_node; uint32_t index[MAX_FRIEND_CLIENTS]; for(i = 0; i < num_friends; i++) { for(j = 0; j < MAX_FRIEND_CLIENTS; j++) { if(friends_list[i].client_list[j].timestamp + Kill_NODE_TIMEOUT > temp_time)//if node is not dead. { if((friends_list[i].client_list[j].last_pinged + PING_INTERVAL) <= temp_time) { pingreq(friends_list[i].client_list[j].ip_port, friends_list[i].client_list[j].client_id); friends_list[i].client_list[j].last_pinged = temp_time; } if(friends_list[i].client_list[j].timestamp + BAD_NODE_TIMEOUT > temp_time)//if node is good. { index[num_nodes] = j; num_nodes++; } } } if(friends_list[i].lastgetnode + GET_NODE_INTERVAL <= temp_time && num_nodes != 0) { rand_node = rand() % num_nodes; getnodes(friends_list[i].client_list[index[rand_node]].ip_port, friends_list[i].client_list[index[rand_node]].client_id, friends_list[i].client_id); friends_list[i].lastgetnode = temp_time; } } } static uint32_t close_lastgetnodes; //Ping each client in the close nodes list every 60 seconds. //Send a get nodes request every 20 seconds to a random good node in the list. void doClose()//tested { uint32_t i; uint32_t temp_time = unix_time(); uint32_t num_nodes = 0; uint32_t rand_node; uint32_t index[LCLIENT_LIST]; for(i = 0; i < LCLIENT_LIST; i++) { if(close_clientlist[i].timestamp + Kill_NODE_TIMEOUT > temp_time)//if node is not dead. { if((close_clientlist[i].last_pinged + PING_INTERVAL) <= temp_time) { pingreq(close_clientlist[i].ip_port, close_clientlist[i].client_id); close_clientlist[i].last_pinged = temp_time; } if(close_clientlist[i].timestamp + BAD_NODE_TIMEOUT > temp_time)//if node is good. { index[num_nodes] = i; num_nodes++; } } } if(close_lastgetnodes + GET_NODE_INTERVAL <= temp_time && num_nodes != 0) { rand_node = rand() % num_nodes; getnodes(close_clientlist[index[rand_node]].ip_port, close_clientlist[index[rand_node]].client_id, self_public_key); close_lastgetnodes = temp_time; } } void doDHT() { doClose(); doDHTFriends(); } void DHT_bootstrap(IP_Port ip_port, uint8_t * public_key) { getnodes(ip_port, public_key, self_public_key); } //get the size of the DHT (for saving) uint32_t DHT_size() { return sizeof(close_clientlist) + sizeof(Friend) * num_friends; } //save the DHT in data where data is an array of size DHT_size() void DHT_save(uint8_t * data) { memcpy(data, close_clientlist, sizeof(close_clientlist)); memcpy(data + sizeof(close_clientlist), friends_list, sizeof(Friend) * num_friends); } //load the DHT from data of size size; //return -1 if failure //return 0 if success int DHT_load(uint8_t * data, uint32_t size) { if(size < sizeof(close_clientlist)) { return -1; } if((size - sizeof(close_clientlist)) % sizeof(Friend) != 0) { return -1; } uint32_t i, j; //uint32_t temp_time = unix_time(); uint16_t temp; temp = (size - sizeof(close_clientlist))/sizeof(Friend); if(temp != 0) { Friend * tempfriends_list = (Friend *)(data + sizeof(close_clientlist)); for(i = 0; i < temp; i++) { DHT_addfriend(tempfriends_list[i].client_id); for(j = 0; j < MAX_FRIEND_CLIENTS; j++) { if(tempfriends_list[i].client_list[j].timestamp != 0) { getnodes(tempfriends_list[i].client_list[j].ip_port, tempfriends_list[i].client_list[j].client_id, tempfriends_list[i].client_id); } } } } Client_data * tempclose_clientlist = (Client_data *)data; for(i = 0; i < LCLIENT_LIST; i++) { if(tempclose_clientlist[i].timestamp != 0) { DHT_bootstrap(tempclose_clientlist[i].ip_port, tempclose_clientlist[i].client_id); } } return 0; } //returns 0 if we are not connected to the DHT //returns 1 if we are int DHT_isconnected() { uint32_t i; uint32_t temp_time = unix_time(); for(i = 0; i < LCLIENT_LIST; i++) { if(close_clientlist[i].timestamp + BAD_NODE_TIMEOUT > temp_time) { return 1; } } return 0; }