/* This file is part of tgl-library This library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. This library 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 Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this library; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA Copyright Nikolay Durov, Andrey Lopatin 2012-2013 Vitaly Valtman 2013-2015 */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #define _FILE_OFFSET_BITS 64 #include #include #include #include #include #if defined(WIN32) || defined(_WIN32) #include #include #include #include #define WIN32_LEAN_AND_MEAN #include #undef WIN32_LEAN_AND_MEAN #else #include #include #include #include #include #include #endif #include #if defined(__FreeBSD__) || defined(__OpenBSD__) #include #endif #include #include #include #include #include //#include "telegram.h" #include "queries.h" //#include "loop.h" #include "tgl-structures.h" #include "tgl-binlog.h" #include "auto.h" #include "auto/auto-types.h" #include "auto/auto-skip.h" #include "tgl.h" #include "mtproto-client.h" #include "tools.h" #include "tree.h" #include "updates.h" #include "mtproto-utils.h" #include "auto.h" #include "tgl-methods-in.h" #if defined(__FreeBSD__) #define __builtin_bswap32(x) bswap32(x) #endif #if defined(__OpenBSD__) #define __builtin_bswap32(x) __swap32gen(x) #endif #define sha1 SHA1 #include "mtproto-common.h" #define MAX_NET_RES (1L << 16) //extern int log_level; static long long generate_next_msg_id (struct tgl_state *TLS, struct tgl_dc *DC, struct tgl_session *S); static double get_server_time (struct tgl_dc *DC); #if !defined(HAVE___BUILTIN_BSWAP32) && !defined(__FreeBSD__) && !defined(__OpenBSD__) static inline unsigned __builtin_bswap32(unsigned x) { return ((x << 24) & 0xff000000 ) | ((x << 8) & 0x00ff0000 ) | ((x >> 8) & 0x0000ff00 ) | ((x >> 24) & 0x000000ff ); } #endif // for statistic only static int total_packets_sent; static long long total_data_sent; static int rpc_execute (struct tgl_state *TLS, struct connection *c, int op, int len); static int rpc_becomes_ready (struct tgl_state *TLS, struct connection *c); static int rpc_close (struct tgl_state *TLS, struct connection *c); static double get_utime (int clock_id) { struct timespec T; tgl_my_clock_gettime (clock_id, &T); return T.tv_sec + (double) T.tv_nsec * 1e-9; } #define MAX_RESPONSE_SIZE (1L << 24) static RSA *rsa_load_public_key (struct tgl_state *TLS, const char *public_key_name) { #if defined(_MSC_VER) && _MSC_VER >= 1400 FILE * f = NULL; errno_t err = fopen_s(&f, public_key_name, "r"); if (err != 0) { #else FILE *f = fopen (public_key_name, "r"); if (f == NULL) { #endif vlogprintf (E_WARNING, "Couldn't open public key file: %s\n", public_key_name); return NULL; } RSA *res = PEM_read_RSAPublicKey (f, NULL, NULL, NULL); fclose (f); if (res == NULL) { vlogprintf (E_WARNING, "PEM_read_RSAPublicKey returns NULL.\n"); return NULL; } vlogprintf (E_NOTICE, "public key '%s' loaded successfully\n", public_key_name); return res; } /* * * UNAUTHORIZED (DH KEY EXCHANGE) PROTOCOL PART * */ #define ENCRYPT_BUFFER_INTS 16384 static int encrypt_buffer[ENCRYPT_BUFFER_INTS]; #define DECRYPT_BUFFER_INTS 16384 static int decrypt_buffer[ENCRYPT_BUFFER_INTS]; static int encrypt_packet_buffer (struct tgl_state *TLS, struct tgl_dc *DC) { RSA *key = TLS->rsa_key_loaded[DC->rsa_key_idx]; return tgl_pad_rsa_encrypt (TLS, (char *) packet_buffer, (packet_ptr - packet_buffer) * 4, (char *) encrypt_buffer, ENCRYPT_BUFFER_INTS * 4, key->n, key->e); } static int encrypt_packet_buffer_aes_unauth (const char server_nonce[16], const char hidden_client_nonce[32]) { tgl_init_aes_unauth (server_nonce, hidden_client_nonce, AES_ENCRYPT); return tgl_pad_aes_encrypt ((char *) packet_buffer, (packet_ptr - packet_buffer) * 4, (char *) encrypt_buffer, ENCRYPT_BUFFER_INTS * 4); } // // Used in unauthorized part of protocol // static int rpc_send_packet (struct tgl_state *TLS, struct connection *c) { static struct { long long auth_key_id; long long out_msg_id; int msg_len; } unenc_msg_header; int len = (packet_ptr - packet_buffer) * 4; TLS->net_methods->incr_out_packet_num (c); struct tgl_dc *DC = TLS->net_methods->get_dc (c); struct tgl_session *S = TLS->net_methods->get_session (c); unenc_msg_header.out_msg_id = generate_next_msg_id (TLS, DC, S); unenc_msg_header.msg_len = len; int total_len = len + 20; assert (total_len > 0 && !(total_len & 0xfc000003)); total_len >>= 2; vlogprintf (E_DEBUG, "writing packet: total_len = %d, len = %d\n", total_len, len); if (total_len < 0x7f) { assert (TLS->net_methods->write_out (c, &total_len, 1) == 1); } else { total_len = (total_len << 8) | 0x7f; assert (TLS->net_methods->write_out (c, &total_len, 4) == 4); } TLS->net_methods->write_out (c, &unenc_msg_header, 20); TLS->net_methods->write_out (c, packet_buffer, len); TLS->net_methods->flush_out (c); total_packets_sent ++; total_data_sent += total_len; return 1; } static int rpc_send_message (struct tgl_state *TLS, struct connection *c, void *data, int len) { assert (len > 0 && !(len & 0xfc000003)); int total_len = len >> 2; if (total_len < 0x7f) { assert (TLS->net_methods->write_out (c, &total_len, 1) == 1); } else { total_len = (total_len << 8) | 0x7f; assert (TLS->net_methods->write_out (c, &total_len, 4) == 4); } TLS->net_methods->incr_out_packet_num (c); assert (TLS->net_methods->write_out (c, data, len) == len); TLS->net_methods->flush_out (c); total_packets_sent ++; total_data_sent += total_len; return 1; } // // State machine. See description at // https://core.telegram.org/mtproto/auth_key // static int check_unauthorized_header (struct tgl_state *TLS) { long long auth_key_id = fetch_long (); if (auth_key_id) { vlogprintf (E_ERROR, "ERROR: auth_key_id should be NULL\n"); return -1; } fetch_long (); // msg_id int len = fetch_int (); if (len != 4 * (in_end - in_ptr)) { vlogprintf (E_ERROR, "ERROR: length mismatch\n"); return -1; } return 0; } /* {{{ REQ_PQ */ // req_pq#60469778 nonce:int128 = ResPQ static int send_req_pq_packet (struct tgl_state *TLS, struct connection *c) { struct tgl_dc *DC = TLS->net_methods->get_dc (c); assert (DC->state == st_init); tglt_secure_random (DC->nonce, 16); clear_packet (); out_int (CODE_req_pq); out_ints ((int *)DC->nonce, 4); rpc_send_packet (TLS, c); DC->state = st_reqpq_sent; return 1; } // req_pq#60469778 nonce:int128 = ResPQ static int send_req_pq_temp_packet (struct tgl_state *TLS, struct connection *c) { struct tgl_dc *DC = TLS->net_methods->get_dc (c); assert (DC->state == st_authorized); tglt_secure_random (DC->nonce, 16); clear_packet (); out_int (CODE_req_pq); out_ints ((int *)DC->nonce, 4); rpc_send_packet (TLS, c); DC->state = st_reqpq_sent_temp; return 1; } /* }}} */ /* {{{ REQ DH */ // req_DH_params#d712e4be nonce:int128 server_nonce:int128 p:string q:string public_key_fingerprint:long encrypted_data:string = Server_DH_Params; // p_q_inner_data#83c95aec pq:string p:string q:string nonce:int128 server_nonce:int128 new_nonce:int256 = P_Q_inner_data; // p_q_inner_data_temp#3c6a84d4 pq:string p:string q:string nonce:int128 server_nonce:int128 new_nonce:int256 expires_in:int = P_Q_inner_data; static void send_req_dh_packet (struct tgl_state *TLS, struct connection *c, BIGNUM *pq, int temp_key) { struct tgl_dc *DC = TLS->net_methods->get_dc (c); BIGNUM *p = BN_new (); BIGNUM *q = BN_new (); assert (bn_factorize (pq, p, q) >= 0); clear_packet (); packet_ptr += 5; out_int (temp_key ? CODE_p_q_inner_data_temp : CODE_p_q_inner_data); out_bignum (pq); out_bignum (p); out_bignum (q); out_ints ((int *) DC->nonce, 4); out_ints ((int *) DC->server_nonce, 4); tglt_secure_random (DC->new_nonce, 32); out_ints ((int *) DC->new_nonce, 8); if (temp_key) { out_int (TLS->temp_key_expire_time); } sha1 ((unsigned char *) (packet_buffer + 5), (packet_ptr - packet_buffer - 5) * 4, (unsigned char *) packet_buffer); int l = encrypt_packet_buffer (TLS, DC); clear_packet (); out_int (CODE_req_DH_params); out_ints ((int *) DC->nonce, 4); out_ints ((int *) DC->server_nonce, 4); out_bignum (p); out_bignum (q); out_long (TLS->rsa_key_fingerprint[DC->rsa_key_idx]); out_cstring ((char *) encrypt_buffer, l); BN_free (p); BN_free (q); DC->state = temp_key ? st_reqdh_sent_temp : st_reqdh_sent; rpc_send_packet (TLS, c); } /* }}} */ /* {{{ SEND DH PARAMS */ // set_client_DH_params#f5045f1f nonce:int128 server_nonce:int128 encrypted_data:string = Set_client_DH_params_answer; // client_DH_inner_data#6643b654 nonce:int128 server_nonce:int128 retry_id:long g_b:string = Client_DH_Inner_Data static void send_dh_params (struct tgl_state *TLS, struct connection *c, BIGNUM *dh_prime, BIGNUM *g_a, int g, int temp_key) { struct tgl_dc *DC = TLS->net_methods->get_dc (c); clear_packet (); packet_ptr += 5; out_int (CODE_client_DH_inner_data); out_ints ((int *) DC->nonce, 4); out_ints ((int *) DC->server_nonce, 4); out_long (0); BIGNUM *dh_g = BN_new (); ensure (BN_set_word (dh_g, g)); static unsigned char s_power[256]; tglt_secure_random (s_power, 256); BIGNUM *dh_power = BN_bin2bn ((unsigned char *)s_power, 256, 0); ensure_ptr (dh_power); BIGNUM *y = BN_new (); ensure_ptr (y); ensure (BN_mod_exp (y, dh_g, dh_power, dh_prime, TLS->BN_ctx)); out_bignum (y); BN_free (y); BIGNUM *auth_key_num = BN_new (); ensure (BN_mod_exp (auth_key_num, g_a, dh_power, dh_prime, TLS->BN_ctx)); int l = BN_num_bytes (auth_key_num); assert (l >= 250 && l <= 256); assert (BN_bn2bin (auth_key_num, (unsigned char *)(temp_key ? DC->temp_auth_key : DC->auth_key))); if (l < 256) { char *key = temp_key ? DC->temp_auth_key : DC->auth_key; memmove (key + 256 - l, key, l); memset (key, 0, 256 - l); } BN_free (dh_power); BN_free (auth_key_num); BN_free (dh_g); sha1 ((unsigned char *) (packet_buffer + 5), (packet_ptr - packet_buffer - 5) * 4, (unsigned char *) packet_buffer); l = encrypt_packet_buffer_aes_unauth (DC->server_nonce, DC->new_nonce); clear_packet (); out_int (CODE_set_client_DH_params); out_ints ((int *) DC->nonce, 4); out_ints ((int *) DC->server_nonce, 4); out_cstring ((char *) encrypt_buffer, l); DC->state = temp_key ? st_client_dh_sent_temp : st_client_dh_sent;; rpc_send_packet (TLS, c); } /* }}} */ /* {{{ RECV RESPQ */ // resPQ#05162463 nonce:int128 server_nonce:int128 pq:string server_public_key_fingerprints:Vector long = ResPQ static int process_respq_answer (struct tgl_state *TLS, struct connection *c, char *packet, int len, int temp_key) { assert (!(len & 3)); in_ptr = (int *)packet; in_end = in_ptr + (len / 4); if (check_unauthorized_header (TLS) < 0) { return -1; } int *in_save = in_ptr; if (skip_type_any (TYPE_TO_PARAM (res_p_q)) < 0 || in_ptr != in_end) { vlogprintf (E_ERROR, "can not parse req_p_q answer\n"); return -1; } in_ptr = in_save; struct tgl_dc *DC = TLS->net_methods->get_dc (c); assert (fetch_int() == CODE_res_p_q); static int tmp[4]; fetch_ints (tmp, 4); if (memcmp (tmp, DC->nonce, 16)) { vlogprintf (E_ERROR, "nonce mismatch\n"); return -1; } fetch_ints (DC->server_nonce, 4); BIGNUM *pq = BN_new (); assert (fetch_bignum (pq) >= 0); assert (fetch_int () == CODE_vector); int fingerprints_num = fetch_int (); assert (fingerprints_num >= 0); DC->rsa_key_idx = -1; int i; for (i = 0; i < fingerprints_num; i++) { int j; long long fprint = fetch_long (); for (j = 0; j < TLS->rsa_key_num; j++) { if (TLS->rsa_key_loaded[j]) { if (fprint == TLS->rsa_key_fingerprint[j]) { DC->rsa_key_idx = j; break; } } } } assert (in_ptr == in_end); if (DC->rsa_key_idx == -1) { vlogprintf (E_ERROR, "fatal: don't have any matching keys\n"); return -1; } send_req_dh_packet (TLS, c, pq, temp_key); BN_free (pq); return 1; } /* }}} */ /* {{{ RECV DH */ // server_DH_params_fail#79cb045d nonce:int128 server_nonce:int128 new_nonce_hash:int128 = Server_DH_Params; // server_DH_params_ok#d0e8075c nonce:int128 server_nonce:int128 encrypted_answer:string = Server_DH_Params; // server_DH_inner_data#b5890dba nonce:int128 server_nonce:int128 g:int dh_prime:string g_a:string server_time:int = Server_DH_inner_data; static int process_dh_answer (struct tgl_state *TLS, struct connection *c, char *packet, int len, int temp_key) { assert (!(len & 3)); in_ptr = (int *)packet; in_end = in_ptr + (len / 4); if (check_unauthorized_header (TLS) < 0) { return -1; } int *in_save = in_ptr; if (skip_type_any (TYPE_TO_PARAM (server_d_h_params)) < 0 || in_ptr != in_end) { vlogprintf (E_ERROR, "can not parse server_DH_params answer\n"); return -1; } in_ptr = in_save; struct tgl_dc *DC = TLS->net_methods->get_dc (c); unsigned op = fetch_int (); assert (op == CODE_server__d_h_params_ok || op == CODE_server__d_h_params_fail); int tmp[4]; fetch_ints (tmp, 4); if (memcmp (tmp, DC->nonce, 16)) { vlogprintf (E_ERROR, "nonce mismatch\n"); return -1; } assert (!memcmp (tmp, DC->nonce, 16)); fetch_ints (tmp, 4); if (memcmp (tmp, DC->server_nonce, 16)) { vlogprintf (E_ERROR, "nonce mismatch\n"); return -1; } assert (!memcmp (tmp, DC->server_nonce, 16)); if (op == CODE_server__d_h_params_fail) { vlogprintf (E_ERROR, "DH params fail\n"); return -1; } tgl_init_aes_unauth (DC->server_nonce, DC->new_nonce, AES_DECRYPT); int l = prefetch_strlen (); assert (l >= 0); if (!l) { vlogprintf (E_ERROR, "non-empty encrypted part expected\n"); return -1; } l = tgl_pad_aes_decrypt (fetch_str (l), l, (char *) decrypt_buffer, DECRYPT_BUFFER_INTS * 4 - 16); assert (in_ptr == in_end); in_ptr = decrypt_buffer + 5; in_end = decrypt_buffer + (l >> 2); if (skip_type_any (TYPE_TO_PARAM (server_d_h_inner_data)) < 0) { vlogprintf (E_ERROR, "can not parse server_DH_inner_data answer\n"); return -1; } in_ptr = decrypt_buffer + 5; assert (fetch_int () == (int)CODE_server_DH_inner_data); fetch_ints (tmp, 4); if (memcmp (tmp, DC->nonce, 16)) { vlogprintf (E_ERROR, "nonce mismatch\n"); return -1; } assert (!memcmp (tmp, DC->nonce, 16)); fetch_ints (tmp, 4); if (memcmp (tmp, DC->server_nonce, 16)) { vlogprintf (E_ERROR, "nonce mismatch\n"); return -1; } assert (!memcmp (tmp, DC->server_nonce, 16)); int g = fetch_int (); BIGNUM *dh_prime = BN_new (); BIGNUM *g_a = BN_new (); assert (fetch_bignum (dh_prime) > 0); assert (fetch_bignum (g_a) > 0); if (tglmp_check_DH_params (TLS, dh_prime, g) < 0) { vlogprintf (E_ERROR, "bad DH params\n"); return -1; } if (tglmp_check_g_a (TLS, dh_prime, g_a) < 0) { vlogprintf (E_ERROR, "bad dh_prime\n"); return -1; } int server_time = fetch_int (); assert (in_ptr <= in_end); static char sha1_buffer[20]; sha1 ((unsigned char *) decrypt_buffer + 20, (in_ptr - decrypt_buffer - 5) * 4, (unsigned char *) sha1_buffer); if (memcmp (decrypt_buffer, sha1_buffer, 20)) { vlogprintf (E_ERROR, "bad encrypted message SHA1\n"); return -1; } if ((char *) in_end - (char *) in_ptr >= 16) { vlogprintf (E_ERROR, "too much padding\n"); return -1; } DC->server_time_delta = server_time - get_utime (CLOCK_REALTIME); DC->server_time_udelta = server_time - get_utime (CLOCK_MONOTONIC); send_dh_params (TLS, c, dh_prime, g_a, g, temp_key); BN_free (dh_prime); BN_free (g_a); return 1; } /* }}} */ static void create_temp_auth_key (struct tgl_state *TLS, struct connection *c) { assert (TLS->enable_pfs); send_req_pq_temp_packet (TLS, c); } int tglmp_encrypt_inner_temp (struct tgl_state *TLS, struct connection *c, int *msg, int msg_ints, int useful, void *data, long long msg_id); static long long msg_id_override; static void mpc_on_get_config (struct tgl_state *TLS, void *extra, int success); static void bind_temp_auth_key (struct tgl_state *TLS, struct connection *c); /* {{{ RECV AUTH COMPLETE */ // dh_gen_ok#3bcbf734 nonce:int128 server_nonce:int128 new_nonce_hash1:int128 = Set_client_DH_params_answer; // dh_gen_retry#46dc1fb9 nonce:int128 server_nonce:int128 new_nonce_hash2:int128 = Set_client_DH_params_answer; // dh_gen_fail#a69dae02 nonce:int128 server_nonce:int128 new_nonce_hash3:int128 = Set_client_DH_params_answer; static int process_auth_complete (struct tgl_state *TLS, struct connection *c, char *packet, int len, int temp_key) { struct tgl_dc *DC = TLS->net_methods->get_dc (c); assert (!(len & 3)); in_ptr = (int *)packet; in_end = in_ptr + (len / 4); if (check_unauthorized_header (TLS) < 0) { return -1; } int *in_save = in_ptr; if (skip_type_any (TYPE_TO_PARAM (set_client_d_h_params_answer)) < 0 || in_ptr != in_end) { vlogprintf (E_ERROR, "can not parse server_DH_params answer\n"); return -1; } in_ptr = in_save; unsigned op = fetch_int (); assert (op == CODE_dh_gen_ok || op == CODE_dh_gen_retry || op == CODE_dh_gen_fail); int tmp[4]; fetch_ints (tmp, 4); if (memcmp (DC->nonce, tmp, 16)) { vlogprintf (E_ERROR, "nonce mismatch\n"); return -1; } fetch_ints (tmp, 4); if (memcmp (DC->server_nonce, tmp, 16)) { vlogprintf (E_ERROR, "nonce mismatch\n"); return -1; } if (op != CODE_dh_gen_ok) { vlogprintf (E_ERROR, "something bad. Retry regen\n"); return -1; } fetch_ints (tmp, 4); static unsigned char th[44], sha1_buffer[20]; memcpy (th, DC->new_nonce, 32); th[32] = 1; if (!temp_key) { sha1 ((unsigned char *)DC->auth_key, 256, sha1_buffer); } else { sha1 ((unsigned char *)DC->temp_auth_key, 256, sha1_buffer); } memcpy (th + 33, sha1_buffer, 8); sha1 (th, 41, sha1_buffer); if (memcmp (tmp, sha1_buffer + 4, 16)) { vlogprintf (E_ERROR, "hash mismatch\n"); return -1; } if (!temp_key) { bl_do_set_auth_key (TLS, DC->id, (unsigned char *)DC->auth_key); sha1 ((unsigned char *)DC->auth_key, 256, sha1_buffer); } else { sha1 ((unsigned char *)DC->temp_auth_key, 256, sha1_buffer); DC->temp_auth_key_id = *(long long *)(sha1_buffer + 12); } DC->server_salt = *(long long *)DC->server_nonce ^ *(long long *)DC->new_nonce; DC->state = st_authorized; vlogprintf (E_DEBUG, "Auth success\n"); if (temp_key) { bind_temp_auth_key (TLS, c); } else { DC->flags |= 1; if (TLS->enable_pfs) { create_temp_auth_key (TLS, c); } else { DC->temp_auth_key_id = DC->auth_key_id; memcpy (DC->temp_auth_key, DC->auth_key, 256); DC->flags |= 2; if (!(DC->flags & 4)) { tgl_do_help_get_config_dc (TLS, DC, mpc_on_get_config, DC); } } } return 1; } /* }}} */ static void bind_temp_auth_key (struct tgl_state *TLS, struct connection *c) { struct tgl_dc *DC = TLS->net_methods->get_dc (c); if (DC->temp_auth_key_bind_query_id) { tglq_query_delete (TLS, DC->temp_auth_key_bind_query_id); } struct tgl_session *S = TLS->net_methods->get_session (c); long long msg_id = generate_next_msg_id (TLS, DC, S); clear_packet (); out_int (CODE_bind_auth_key_inner); long long rand; tglt_secure_random (&rand, 8); out_long (rand); out_long (DC->temp_auth_key_id); out_long (DC->auth_key_id); if (!S->session_id) { tglt_secure_random (&S->session_id, 8); } out_long (S->session_id); int expires = (int)time (0) + DC->server_time_delta + TLS->temp_key_expire_time; out_int (expires); static int data[1000]; int len = tglmp_encrypt_inner_temp (TLS, c, packet_buffer, packet_ptr - packet_buffer, 0, data, msg_id); msg_id_override = msg_id; DC->temp_auth_key_bind_query_id = msg_id; tgl_do_send_bind_temp_key (TLS, DC, rand, expires, (void *)data, len, msg_id); msg_id_override = 0; } /* * * AUTHORIZED (MAIN) PROTOCOL PART * */ static struct encrypted_message enc_msg; static double get_server_time (struct tgl_dc *DC) { //if (!DC->server_time_udelta) { // DC->server_time_udelta = get_utime (CLOCK_REALTIME) - get_utime (CLOCK_MONOTONIC); //} return get_utime (CLOCK_MONOTONIC) + DC->server_time_udelta; } static long long generate_next_msg_id (struct tgl_state *TLS, struct tgl_dc *DC, struct tgl_session *S) { long long next_id = (long long) (get_server_time (DC) * (1LL << 32)) & -4; if (next_id <= S->last_msg_id) { next_id = S->last_msg_id += 4; } else { S->last_msg_id = next_id; } return next_id; } static void init_enc_msg (struct tgl_state *TLS, struct tgl_session *S, int useful) { struct tgl_dc *DC = S->dc; assert (DC->state == st_authorized); assert (DC->temp_auth_key_id); vlogprintf (E_DEBUG, "temp_auth_key_id = 0x%016llx, auth_key_id = 0x%016llx\n", DC->temp_auth_key_id, DC->auth_key_id); enc_msg.auth_key_id = DC->temp_auth_key_id; enc_msg.server_salt = DC->server_salt; if (!S->session_id) { tglt_secure_random (&S->session_id, 8); } enc_msg.session_id = S->session_id; enc_msg.msg_id = msg_id_override ? msg_id_override : generate_next_msg_id (TLS, DC, S); enc_msg.seq_no = S->seq_no; if (useful) { enc_msg.seq_no |= 1; } S->seq_no += 2; }; static void init_enc_msg_inner_temp (struct tgl_dc *DC, long long msg_id) { enc_msg.auth_key_id = DC->auth_key_id; tglt_secure_random (&enc_msg.server_salt, 8); tglt_secure_random (&enc_msg.session_id, 8); enc_msg.msg_id = msg_id; enc_msg.seq_no = 0; }; static int aes_encrypt_message (struct tgl_state *TLS, char *key, struct encrypted_message *enc) { unsigned char sha1_buffer[20]; const int MINSZ = offsetof (struct encrypted_message, message); const int UNENCSZ = offsetof (struct encrypted_message, server_salt); int enc_len = (MINSZ - UNENCSZ) + enc->msg_len; assert (enc->msg_len >= 0 && enc->msg_len <= MAX_MESSAGE_INTS * 4 - 16 && !(enc->msg_len & 3)); sha1 ((unsigned char *) &enc->server_salt, enc_len, sha1_buffer); vlogprintf (E_DEBUG, "sending message with sha1 %08x\n", *(int *)sha1_buffer); memcpy (enc->msg_key, sha1_buffer + 4, 16); tgl_init_aes_auth (key, enc->msg_key, AES_ENCRYPT); return tgl_pad_aes_encrypt ((char *) &enc->server_salt, enc_len, (char *) &enc->server_salt, MAX_MESSAGE_INTS * 4 + (MINSZ - UNENCSZ)); } long long tglmp_encrypt_send_message (struct tgl_state *TLS, struct connection *c, int *msg, int msg_ints, int flags) { struct tgl_dc *DC = TLS->net_methods->get_dc (c); struct tgl_session *S = TLS->net_methods->get_session (c); assert (S); if (!(DC->flags & 4) && !(flags & 2)) { return generate_next_msg_id (TLS, DC, S); } const int UNENCSZ = offsetof (struct encrypted_message, server_salt); if (msg_ints <= 0 || msg_ints > MAX_MESSAGE_INTS - 4) { return -1; } if (msg) { memcpy (enc_msg.message, msg, msg_ints * 4); enc_msg.msg_len = msg_ints * 4; } else { if ((enc_msg.msg_len & 0x80000003) || enc_msg.msg_len > MAX_MESSAGE_INTS * 4 - 16) { return -1; } } init_enc_msg (TLS, S, flags & 1); int l = aes_encrypt_message (TLS, DC->temp_auth_key, &enc_msg); assert (l > 0); rpc_send_message (TLS, c, &enc_msg, l + UNENCSZ); return S->last_msg_id; } int tglmp_encrypt_inner_temp (struct tgl_state *TLS, struct connection *c, int *msg, int msg_ints, int useful, void *data, long long msg_id) { struct tgl_dc *DC = TLS->net_methods->get_dc (c); struct tgl_session *S = TLS->net_methods->get_session (c); assert (S); const int UNENCSZ = offsetof (struct encrypted_message, server_salt); if (msg_ints <= 0 || msg_ints > MAX_MESSAGE_INTS - 4) { return -1; } memcpy (enc_msg.message, msg, msg_ints * 4); enc_msg.msg_len = msg_ints * 4; init_enc_msg_inner_temp (DC, msg_id); int l = aes_encrypt_message (TLS, DC->auth_key, &enc_msg); assert (l > 0); //rpc_send_message (c, &enc_msg, l + UNENCSZ); memcpy (data, &enc_msg, l + UNENCSZ); return l + UNENCSZ; } static int rpc_execute_answer (struct tgl_state *TLS, struct connection *c, long long msg_id); static int work_container (struct tgl_state *TLS, struct connection *c, long long msg_id) { vlogprintf (E_DEBUG, "work_container: msg_id = %"_PRINTF_INT64_"d\n", msg_id); assert (fetch_int () == CODE_msg_container); int n = fetch_int (); int i; for (i = 0; i < n; i++) { long long id = fetch_long (); //int seqno = fetch_int (); fetch_int (); // seq_no if (id & 1) { tgln_insert_msg_id (TLS, TLS->net_methods->get_session (c), id); } int bytes = fetch_int (); int *t = in_end; in_end = in_ptr + (bytes / 4); int r = rpc_execute_answer (TLS, c, id); if (r < 0) { return -1; } assert (in_ptr == in_end); in_end = t; } return 0; } static int work_new_session_created (struct tgl_state *TLS, struct connection *c, long long msg_id) { vlogprintf (E_DEBUG, "work_new_session_created: msg_id = %"_PRINTF_INT64_"d\n", msg_id); assert (fetch_int () == (int)CODE_new_session_created); fetch_long (); // first message id fetch_long (); // unique_id TLS->net_methods->get_dc (c)->server_salt = fetch_long (); if (TLS->started && !(TLS->locks & TGL_LOCK_DIFF) && (TLS->DC_working->flags & TGLDCF_LOGGED_IN)) { tgl_do_get_difference (TLS, 0, 0, 0); } return 0; } static int work_msgs_ack (struct tgl_state *TLS, struct connection *c, long long msg_id) { vlogprintf (E_DEBUG, "work_msgs_ack: msg_id = %"_PRINTF_INT64_"d\n", msg_id); assert (fetch_int () == CODE_msgs_ack); assert (fetch_int () == CODE_vector); int n = fetch_int (); int i; for (i = 0; i < n; i++) { long long id = fetch_long (); vlogprintf (E_DEBUG + 1, "ack for %"_PRINTF_INT64_"d\n", id); tglq_query_ack (TLS, id); } return 0; } static int work_rpc_result (struct tgl_state *TLS, struct connection *c, long long msg_id) { vlogprintf (E_DEBUG, "work_rpc_result: msg_id = %"_PRINTF_INT64_"d\n", msg_id); assert (fetch_int () == (int)CODE_rpc_result); long long id = fetch_long (); int op = prefetch_int (); if (op == CODE_rpc_error) { return tglq_query_error (TLS, id); } else { return tglq_query_result (TLS, id); } } #define MAX_PACKED_SIZE (1 << 24) static int work_packed (struct tgl_state *TLS, struct connection *c, long long msg_id) { assert (fetch_int () == CODE_gzip_packed); static int in_gzip; static int buf[MAX_PACKED_SIZE >> 2]; assert (!in_gzip); in_gzip = 1; int l = prefetch_strlen (); char *s = fetch_str (l); int total_out = tgl_inflate (s, l, buf, MAX_PACKED_SIZE); int *end = in_ptr; int *eend = in_end; //assert (total_out % 4 == 0); in_ptr = buf; in_end = in_ptr + total_out / 4; int r = rpc_execute_answer (TLS, c, msg_id); in_ptr = end; in_end = eend; in_gzip = 0; return r; } static int work_bad_server_salt (struct tgl_state *TLS, struct connection *c, long long msg_id) { assert (fetch_int () == (int)CODE_bad_server_salt); long long id = fetch_long (); tglq_query_restart (TLS, id); fetch_int (); // seq_no fetch_int (); // error_code long long new_server_salt = fetch_long (); TLS->net_methods->get_dc (c)->server_salt = new_server_salt; return 0; } static int work_pong (struct tgl_state *TLS, struct connection *c, long long msg_id) { assert (fetch_int () == CODE_pong); fetch_long (); // msg_id fetch_long (); // ping_id return 0; } static int work_detailed_info (struct tgl_state *TLS, struct connection *c, long long msg_id) { assert (fetch_int () == CODE_msg_detailed_info); fetch_long (); // msg_id fetch_long (); // answer_msg_id fetch_int (); // bytes fetch_int (); // status return 0; } static int work_new_detailed_info (struct tgl_state *TLS, struct connection *c, long long msg_id) { assert (fetch_int () == (int)CODE_msg_new_detailed_info); fetch_long (); // answer_msg_id fetch_int (); // bytes fetch_int (); // status return 0; } static int work_bad_msg_notification (struct tgl_state *TLS, struct connection *c, long long msg_id) { assert (fetch_int () == (int)CODE_bad_msg_notification); long long m1 = fetch_long (); int s = fetch_int (); int e = fetch_int (); vlogprintf (E_NOTICE, "bad_msg_notification: msg_id = %"_PRINTF_INT64_"d, seq = %d, error = %d\n", m1, s, e); switch (e) { // Too low msg id case 16: tglq_regen_query (TLS, m1); break; // Too high msg id case 17: tglq_regen_query (TLS, m1); break; default: vlogprintf (E_NOTICE, "bad_msg_notification: msg_id = %"_PRINTF_INT64_"d, seq = %d, error = %d\n", m1, s, e); break; } return -1; } static int rpc_execute_answer (struct tgl_state *TLS, struct connection *c, long long msg_id) { int op = prefetch_int (); switch (op) { case CODE_msg_container: return work_container (TLS, c, msg_id); case CODE_new_session_created: return work_new_session_created (TLS, c, msg_id); case CODE_msgs_ack: return work_msgs_ack (TLS, c, msg_id); case CODE_rpc_result: return work_rpc_result (TLS, c, msg_id); case CODE_update_short: case CODE_updates: case CODE_update_short_message: case CODE_update_short_chat_message: case CODE_updates_too_long: tglu_work_any_updates (TLS); return 0; case CODE_gzip_packed: return work_packed (TLS, c, msg_id); case CODE_bad_server_salt: return work_bad_server_salt (TLS, c, msg_id); case CODE_pong: return work_pong (TLS, c, msg_id); case CODE_msg_detailed_info: return work_detailed_info (TLS, c, msg_id); case CODE_msg_new_detailed_info: return work_new_detailed_info (TLS, c, msg_id); case CODE_bad_msg_notification: return work_bad_msg_notification (TLS, c, msg_id); } vlogprintf (E_WARNING, "Unknown message: %08x\n", op); in_ptr = in_end; // Will not fail due to assertion in_ptr == in_end return 0; } static struct mtproto_methods mtproto_methods; void tgls_free_session (struct tgl_state *TLS, struct tgl_session *S); /* static char *get_ipv6 (struct tgl_state *TLS, int num) { static char res[1<< 10]; if (TLS->test_mode) { switch (num) { case 1: strcpy (res, TG_SERVER_TEST_IPV6_1); break; case 2: strcpy (res, TG_SERVER_TEST_IPV6_2); break; case 3: strcpy (res, TG_SERVER_TEST_IPV6_3); break; default: assert (0); } } else { switch (num) { case 1: strcpy (res, TG_SERVER_IPV6_1); break; case 2: strcpy (res, TG_SERVER_IPV6_2); break; case 3: strcpy (res, TG_SERVER_IPV6_3); break; case 4: strcpy (res, TG_SERVER_IPV6_4); break; case 5: strcpy (res, TG_SERVER_IPV6_5); break; default: assert (0); } } return res; } */ static void create_session_connect (struct tgl_state *TLS, struct tgl_session *S) { struct tgl_dc *DC = S->dc; if (TLS->ipv6_enabled) { S->c = TLS->net_methods->create_connection (TLS, DC->options[1]->ip, DC->options[1]->port, S, DC, &mtproto_methods); } else { S->c = TLS->net_methods->create_connection (TLS, DC->options[0]->ip, DC->options[0]->port, S, DC, &mtproto_methods); } } static void fail_connection (struct tgl_state *TLS, struct connection *c) { struct tgl_session *S = TLS->net_methods->get_session (c); TLS->net_methods->free (c); create_session_connect (TLS, S); } static void fail_session (struct tgl_state *TLS, struct tgl_session *S) { vlogprintf (E_NOTICE, "failing session %"_PRINTF_INT64_"d\n", S->session_id); struct tgl_dc *DC = S->dc; tgls_free_session (TLS, S); DC->sessions[0] = NULL; tglmp_dc_create_session (TLS, DC); } static int process_rpc_message (struct tgl_state *TLS, struct connection *c, struct encrypted_message *enc, int len) { const int MINSZ = offsetof (struct encrypted_message, message); const int UNENCSZ = offsetof (struct encrypted_message, server_salt); vlogprintf (E_DEBUG, "process_rpc_message(), len=%d\n", len); if (len < MINSZ || (len & 15) != (UNENCSZ & 15)) { vlogprintf (E_WARNING, "Incorrect packet from server. Closing connection\n"); fail_connection (TLS, c); return -1; } assert (len >= MINSZ && (len & 15) == (UNENCSZ & 15)); struct tgl_dc *DC = TLS->net_methods->get_dc (c); if (enc->auth_key_id != DC->temp_auth_key_id && enc->auth_key_id != DC->auth_key_id) { vlogprintf (E_WARNING, "received msg from dc %d with auth_key_id %"_PRINTF_INT64_"d (perm_auth_key_id %"_PRINTF_INT64_"d temp_auth_key_id %"_PRINTF_INT64_"d). Dropping\n", DC->id, enc->auth_key_id, DC->auth_key_id, DC->temp_auth_key_id); return 0; } if (enc->auth_key_id == DC->temp_auth_key_id) { assert (enc->auth_key_id == DC->temp_auth_key_id); assert (DC->temp_auth_key_id); tgl_init_aes_auth (DC->temp_auth_key + 8, enc->msg_key, AES_DECRYPT); } else { assert (enc->auth_key_id == DC->auth_key_id); assert (DC->auth_key_id); tgl_init_aes_auth (DC->auth_key + 8, enc->msg_key, AES_DECRYPT); } int l = tgl_pad_aes_decrypt ((char *)&enc->server_salt, len - UNENCSZ, (char *)&enc->server_salt, len - UNENCSZ); assert (l == len - UNENCSZ); if (!(!(enc->msg_len & 3) && enc->msg_len > 0 && enc->msg_len <= len - MINSZ && len - MINSZ - enc->msg_len <= 12)) { vlogprintf (E_WARNING, "Incorrect packet from server. Closing connection\n"); fail_connection (TLS, c); return -1; } assert (!(enc->msg_len & 3) && enc->msg_len > 0 && enc->msg_len <= len - MINSZ && len - MINSZ - enc->msg_len <= 12); struct tgl_session *S = TLS->net_methods->get_session (c); if (!S || S->session_id != enc->session_id) { vlogprintf (E_WARNING, "Message to bad session. Drop.\n"); return 0; } static unsigned char sha1_buffer[20]; sha1 ((void *)&enc->server_salt, enc->msg_len + (MINSZ - UNENCSZ), sha1_buffer); if (memcmp (&enc->msg_key, sha1_buffer + 4, 16)) { vlogprintf (E_WARNING, "Incorrect packet from server. Closing connection\n"); fail_connection (TLS, c); return -1; } assert (!memcmp (&enc->msg_key, sha1_buffer + 4, 16)); int this_server_time = enc->msg_id >> 32LL; if (!S->received_messages) { DC->server_time_delta = this_server_time - get_utime (CLOCK_REALTIME); if (DC->server_time_udelta) { vlogprintf (E_WARNING, "adjusting CLOCK_MONOTONIC delta to %lf\n", DC->server_time_udelta - this_server_time + get_utime (CLOCK_MONOTONIC)); } DC->server_time_udelta = this_server_time - get_utime (CLOCK_MONOTONIC); } double st = get_server_time (DC); if (this_server_time < st - 300 || this_server_time > st + 30) { vlogprintf (E_WARNING, "bad msg time: salt = %"_PRINTF_INT64_"d, session_id = %"_PRINTF_INT64_"d, msg_id = %"_PRINTF_INT64_"d, seq_no = %d, st = %lf, now = %lf\n", enc->server_salt, enc->session_id, enc->msg_id, enc->seq_no, st, get_utime (CLOCK_REALTIME)); fail_session (TLS, S); return -1; } S->received_messages ++; if (DC->server_salt != enc->server_salt) { DC->server_salt = enc->server_salt; } assert (this_server_time >= st - 300 && this_server_time <= st + 30); //assert (enc->msg_id > server_last_msg_id && (enc->msg_id & 3) == 1); vlogprintf (E_DEBUG, "received mesage id %016llx\n", enc->msg_id); //server_last_msg_id = enc->msg_id; //*(long long *)(longpoll_query + 3) = *(long long *)((char *)(&enc->msg_id) + 0x3c); //*(long long *)(longpoll_query + 5) = *(long long *)((char *)(&enc->msg_id) + 0x3c); assert (l >= (MINSZ - UNENCSZ) + 8); //assert (enc->message[0] == CODE_rpc_result && *(long long *)(enc->message + 1) == client_last_msg_id); in_ptr = enc->message; in_end = in_ptr + (enc->msg_len / 4); if (enc->msg_id & 1) { tgln_insert_msg_id (TLS, S, enc->msg_id); } assert (S->session_id == enc->session_id); if (rpc_execute_answer (TLS, c, enc->msg_id) < 0) { fail_session (TLS, S); return -1; } assert (in_ptr == in_end); return 0; } static int rpc_execute (struct tgl_state *TLS, struct connection *c, int op, int len) { struct tgl_dc *DC = TLS->net_methods->get_dc (c); if (len >= MAX_RESPONSE_SIZE/* - 12*/ || len < 0/*12*/) { vlogprintf (E_WARNING, "answer too long (%d bytes), skipping\n", len); return 0; } int Response_len = len; static char Response[MAX_RESPONSE_SIZE]; vlogprintf (E_DEBUG, "Response_len = %d\n", Response_len); assert (TLS->net_methods->read_in (c, Response, Response_len) == Response_len); #if !defined(WIN32) || !defined(_WIN32) setsockopt(c->fd, IPPROTO_TCP, TCP_QUICKACK, (int[]) { 0 }, 4); #endif #if !defined(__MACH__) && !defined(__FreeBSD__) && !defined(__OpenBSD__) && !defined (__CYGWIN__) // setsockopt (c->fd, IPPROTO_TCP, TCP_QUICKACK, (int[]){0}, 4); #endif int o = DC->state; //if (DC->flags & 1) { o = st_authorized;} if (o != st_authorized) { vlogprintf (E_DEBUG, "%s: state = %d\n", __func__, o); } switch (o) { case st_reqpq_sent: process_respq_answer (TLS, c, Response/* + 8*/, Response_len/* - 12*/, 0); return 0; case st_reqdh_sent: process_dh_answer (TLS, c, Response/* + 8*/, Response_len/* - 12*/, 0); return 0; case st_client_dh_sent: process_auth_complete (TLS, c, Response/* + 8*/, Response_len/* - 12*/, 0); return 0; case st_reqpq_sent_temp: process_respq_answer (TLS, c, Response/* + 8*/, Response_len/* - 12*/, 1); return 0; case st_reqdh_sent_temp: process_dh_answer (TLS, c, Response/* + 8*/, Response_len/* - 12*/, 1); return 0; case st_client_dh_sent_temp: process_auth_complete (TLS, c, Response/* + 8*/, Response_len/* - 12*/, 1); return 0; case st_authorized: if (op < 0 && op >= -999) { vlogprintf (E_WARNING, "Server error %d\n", op); } else { return process_rpc_message (TLS, c, (void *)(Response/* + 8*/), Response_len/* - 12*/); } return 0; default: vlogprintf (E_ERROR, "fatal: cannot receive answer in state %d\n", DC->state); exit (2); } return 0; } static int tc_close (struct tgl_state *TLS, struct connection *c, int who) { vlogprintf (E_DEBUG, "outbound rpc connection from dc #%d : closing by %d\n", TLS->net_methods->get_dc(c)->id, who); return 0; } static void mpc_on_get_config (struct tgl_state *TLS, void *extra, int success) { assert (success); struct tgl_dc *DC = extra; DC->flags |= 4; } static int tc_becomes_ready (struct tgl_state *TLS, struct connection *c) { vlogprintf (E_NOTICE, "outbound rpc connection from dc #%d becomed ready\n", TLS->net_methods->get_dc(c)->id); //char byte = 0xef; //assert (TLS->net_methods->write_out (c, &byte, 1) == 1); //TLS->net_methods->flush_out (c); struct tgl_dc *DC = TLS->net_methods->get_dc (c); if (DC->flags & 1) { DC->state = st_authorized; } int o = DC->state; if (o == st_authorized && !TLS->enable_pfs) { DC->temp_auth_key_id = DC->auth_key_id; memcpy (DC->temp_auth_key, DC->auth_key, 256); DC->flags |= 2; } switch (o) { case st_init: send_req_pq_packet (TLS, c); break; case st_authorized: if (!(DC->flags & 2)) { assert (TLS->enable_pfs); if (!DC->temp_auth_key_id) { assert (!DC->temp_auth_key_id); create_temp_auth_key (TLS, c); } else { bind_temp_auth_key (TLS, c); } } else if (!(DC->flags & 4)) { tgl_do_help_get_config_dc (TLS, DC, mpc_on_get_config, DC); } break; default: vlogprintf (E_DEBUG, "c_state = %d\n", DC->state); DC->state = st_init; // previous connection was reset send_req_pq_packet (TLS, c); break; } return 0; } static int rpc_becomes_ready (struct tgl_state *TLS, struct connection *c) { return tc_becomes_ready (TLS, c); } static int rpc_close (struct tgl_state *TLS, struct connection *c) { return tc_close (TLS, c, 0); } #define RANDSEED_PASSWORD_FILENAME NULL #define RANDSEED_PASSWORD_LENGTH 0 void tglmp_on_start (struct tgl_state *TLS) { tgl_prng_seed (TLS, RANDSEED_PASSWORD_FILENAME, RANDSEED_PASSWORD_LENGTH); int i; int ok = 0; for (i = 0; i < TLS->rsa_key_num; i++) { char *key = TLS->rsa_key_list[i]; RSA *res = rsa_load_public_key (TLS, key); if (!res) { vlogprintf (E_WARNING, "Can not load key %s\n", key); TLS->rsa_key_loaded[i] = NULL; } else { ok = 1; TLS->rsa_key_loaded[i] = res; TLS->rsa_key_fingerprint[i] = tgl_do_compute_rsa_key_fingerprint (res); } } if (!ok) { vlogprintf (E_ERROR, "No public keys found\n"); exit (1); } } void tgl_dc_authorize (struct tgl_state *TLS, struct tgl_dc *DC) { //c_state = 0; if (!DC->sessions[0]) { tglmp_dc_create_session (TLS, DC); } vlogprintf (E_DEBUG, "Starting authorization for DC #%d\n", DC->id); //net_loop (0, auth_ok); } #define long_cmp(a,b) ((a) > (b) ? 1 : (a) == (b) ? 0 : -1) DEFINE_TREE(long,long long,long_cmp,0) static int send_all_acks (struct tgl_state *TLS, struct tgl_session *S) { clear_packet (); out_int (CODE_msgs_ack); out_int (CODE_vector); out_int (tree_count_long (S->ack_tree)); while (S->ack_tree) { long long x = tree_get_min_long (S->ack_tree); out_long (x); S->ack_tree = tree_delete_long (S->ack_tree, x); } tglmp_encrypt_send_message (TLS, S->c, packet_buffer, packet_ptr - packet_buffer, 0); return 0; } static void send_all_acks_gateway (struct tgl_state *TLS, void *arg) { send_all_acks (TLS, arg); } void tgln_insert_msg_id (struct tgl_state *TLS, struct tgl_session *S, long long id) { if (!S->ack_tree) { TLS->timer_methods->insert (S->ev, ACK_TIMEOUT); } if (!tree_lookup_long (S->ack_tree, id)) { S->ack_tree = tree_insert_long (S->ack_tree, id, lrand48 ()); } } //extern struct tgl_dc *DC_list[]; static void regen_temp_key_gw (struct tgl_state *TLS, void *arg) { tglmp_regenerate_temp_auth_key (TLS, arg); } struct tgl_dc *tglmp_alloc_dc (struct tgl_state *TLS, int flags, int id, char *ip, int port) { //assert (!TLS->DC_list[id]); if (!TLS->DC_list[id]) { struct tgl_dc *DC = talloc0 (sizeof (*DC)); DC->id = id; TLS->DC_list[id] = DC; if (id > TLS->max_dc_num) { TLS->max_dc_num = id; } DC->ev = TLS->timer_methods->alloc (TLS, regen_temp_key_gw, DC); TLS->timer_methods->insert (DC->ev, 0); } struct tgl_dc *DC = TLS->DC_list[id]; struct tgl_dc_option *O = DC->options[flags & 3]; struct tgl_dc_option *O2 = O; while (O2) { if (!strcmp (O2->ip, ip)) { tfree_str (ip); return DC; } O2 = O2->next; } struct tgl_dc_option *T = talloc (sizeof (*T)); T->ip = ip; T->port = port; T->next = O; DC->options[flags & 3] = T; return DC; } static struct mtproto_methods mtproto_methods = { .execute = rpc_execute, .ready = rpc_becomes_ready, .close = rpc_close }; void tglmp_dc_create_session (struct tgl_state *TLS, struct tgl_dc *DC) { struct tgl_session *S = talloc0 (sizeof (*S)); assert (RAND_pseudo_bytes ((unsigned char *) &S->session_id, 8) >= 0); S->dc = DC; //S->c = TLS->net_methods->create_connection (TLS, DC->ip, DC->port, S, DC, &mtproto_methods); create_session_connect (TLS, S); S->ev = TLS->timer_methods->alloc (TLS, send_all_acks_gateway, S); assert (!DC->sessions[0]); DC->sessions[0] = S; } void tgl_do_send_ping (struct tgl_state *TLS, struct connection *c) { int x[3]; x[0] = CODE_ping; *(long long *)(x + 1) = lrand48 () * (1ll << 32) + lrand48 (); tglmp_encrypt_send_message (TLS, c, x, 3, 0); } void tgl_dc_iterator (struct tgl_state *TLS, void (*iterator)(struct tgl_dc *DC)) { int i; for (i = 0; i <= TLS->max_dc_num; i++) { iterator (TLS->DC_list[i]); } } void tgl_dc_iterator_ex (struct tgl_state *TLS, void (*iterator)(struct tgl_dc *DC, void *extra), void *extra) { int i; for (i = 0; i <= TLS->max_dc_num; i++) { iterator (TLS->DC_list[i], extra); } } void tglmp_regenerate_temp_auth_key (struct tgl_state *TLS, struct tgl_dc *DC) { DC->flags &= ~6; DC->temp_auth_key_id = 0; memset (DC->temp_auth_key, 0, 256); if (!DC->sessions[0]) { tgl_dc_authorize (TLS, DC); return; } struct tgl_session *S = DC->sessions[0]; tglt_secure_random (&S->session_id, 8); S->seq_no = 0; TLS->timer_methods->remove (S->ev); S->ack_tree = tree_clear_long (S->ack_tree); if (DC->state != st_authorized) { return; } if (S->c) { create_temp_auth_key (TLS, S->c); } } void tgls_free_session (struct tgl_state *TLS, struct tgl_session *S) { S->ack_tree = tree_clear_long (S->ack_tree); if (S->ev) { TLS->timer_methods->free (S->ev); } if (S->c) { TLS->net_methods->free (S->c); } tfree (S, sizeof (*S)); } void tgls_free_dc (struct tgl_state *TLS, struct tgl_dc *DC) { //if (DC->ip) { tfree_str (DC->ip); } struct tgl_session *S = DC->sessions[0]; if (S) { tgls_free_session (TLS, S); } if (DC->ev) { TLS->timer_methods->free (DC->ev); } tfree (DC, sizeof (*DC)); } void tgls_free_pubkey (struct tgl_state *TLS) { int i; for (i = 0; i < TLS->rsa_key_num; i++) { if (TLS->rsa_key_loaded[i]) { RSA_free (TLS->rsa_key_loaded[i]); TLS->rsa_key_loaded[i] = NULL; } } }