#define _GNU_SOURCE #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "tpws.h" #include "tpws_conn.h" #include "redirect.h" #include "tamper.h" #include "socks.h" #include "helpers.h" #include "hostlist.h" // keep separate legs counter. counting every time thousands of legs can consume cpu static int legs_local, legs_remote; /* static void count_legs(struct tailhead *conn_list) { tproxy_conn_t *conn = NULL; legs_local = legs_remote = 0; TAILQ_FOREACH(conn, conn_list, conn_ptrs) conn->remote ? legs_remote++ : legs_local++; } */ static void print_legs(void) { VPRINT("Legs : local:%d remote:%d", legs_local, legs_remote) } static bool socks5_send_rep(int fd,uint8_t rep) { s5_rep s5rep; memset(&s5rep,0,sizeof(s5rep)); s5rep.ver = 5; s5rep.rep = rep; s5rep.atyp = S5_ATYP_IP4; return send(fd,&s5rep,sizeof(s5rep),MSG_DONTWAIT)==sizeof(s5rep); } static bool socks5_send_rep_errno(int fd,int errn) { uint8_t rep; switch(errn) { case 0: rep=S5_REP_OK; break; case ECONNREFUSED: rep=S5_REP_CONN_REFUSED; break; case ENETUNREACH: rep=S5_REP_NETWORK_UNREACHABLE; break; case ETIMEDOUT: case EHOSTUNREACH: rep=S5_REP_HOST_UNREACHABLE; break; default: rep=S5_REP_GENERAL_FAILURE; } return socks5_send_rep(fd,rep); } static bool socks4_send_rep(int fd, uint8_t rep) { s4_rep s4rep; memset(&s4rep, 0, sizeof(s4rep)); s4rep.rep = rep; return send(fd, &s4rep, sizeof(s4rep), MSG_DONTWAIT) == sizeof(s4rep); } static bool socks4_send_rep_errno(int fd, int errn) { return socks4_send_rep(fd, errn ? S4_REP_FAILED : S4_REP_OK); } static bool socks_send_rep(uint8_t ver, int fd, uint8_t rep5) { return ver==5 ? socks5_send_rep(fd, rep5) : socks4_send_rep(fd, rep5 ? S4_REP_FAILED : S4_REP_OK); } static bool socks_send_rep_errno(uint8_t ver, int fd, int errn) { return ver==5 ? socks5_send_rep_errno(fd,errn) : socks4_send_rep_errno(fd, errn); } ssize_t send_with_ttl(int fd, const void *buf, size_t len, int flags, int ttl) { ssize_t wr; if (ttl) { DBGPRINT("send_with_ttl %d fd=%d",ttl,fd); if (!set_ttl_hl(fd, ttl)) //fprintf(stderr,"could not set ttl %d to fd=%d\n",ttl,fd); fprintf(stderr,"could not set ttl %d to fd=%d\n",ttl,fd); } wr = send(fd, buf, len, flags); if (ttl) { int e=errno; if (!set_ttl_hl(fd, params.ttl_default)) fprintf(stderr,"could not set ttl %d to fd=%d\n",params.ttl_default,fd); errno=e; } return wr; } static bool send_buffer_create(send_buffer_t *sb, const void *data, size_t len, size_t extra_bytes, int flags, int ttl) { if (sb->data) { fprintf(stderr,"FATAL : send_buffer_create but buffer is not empty\n"); exit(1); } sb->data = malloc(len + extra_bytes); if (!sb->data) { DBGPRINT("send_buffer_create failed. errno=%d",errno) return false; } if (data) memcpy(sb->data,data,len); sb->len = len; sb->pos = 0; sb->ttl = ttl; sb->flags = flags; return true; } static bool send_buffer_realloc(send_buffer_t *sb, size_t extra_bytes) { if (sb->data) { uint8_t *p = (uint8_t*)realloc(sb->data, sb->len + extra_bytes); if (p) { sb->data = p; DBGPRINT("reallocated send_buffer from %zd to %zd", sb->len, sb->len + extra_bytes) return true; } else { DBGPRINT("failed to realloc send_buffer from %zd to %zd", sb->len, sb->len + extra_bytes) } } return false; } static void send_buffer_free(send_buffer_t *sb) { if (sb->data) { free(sb->data); sb->data = NULL; } } static void send_buffers_free(send_buffer_t *sb_array, int count) { for (int i=0;iwr_buf,sizeof(conn->wr_buf)/sizeof(conn->wr_buf[0])); } static bool send_buffer_present(send_buffer_t *sb) { return !!sb->data; } static bool send_buffers_present(send_buffer_t *sb_array, int count) { for(int i=0;idata + sb->pos, sb->len - sb->pos, sb->flags, sb->ttl); DBGPRINT("send_buffer_send len=%zu pos=%zu wr=%zd err=%d",sb->len,sb->pos,wr,errno) if (wr>0) { sb->pos += wr; if (sb->pos >= sb->len) { send_buffer_free(sb); } } else if (wr<0 && errno==EAGAIN) wr=0; return wr; } static ssize_t send_buffers_send(send_buffer_t *sb_array, int count, int fd, size_t *real_wr) { ssize_t wr,twr=0; for (int i=0;iconn_type==CONN_TYPE_SOCKS && conn->socks_state!=S_TCP); } static bool conn_partner_alive(tproxy_conn_t *conn) { return conn->partner && conn->partner->state!=CONN_CLOSED; } static bool conn_buffers_present(tproxy_conn_t *conn) { return send_buffers_present(conn->wr_buf,sizeof(conn->wr_buf)/sizeof(conn->wr_buf[0])); } static ssize_t conn_buffers_send(tproxy_conn_t *conn) { size_t wr,real_twr; wr = send_buffers_send(conn->wr_buf,sizeof(conn->wr_buf)/sizeof(conn->wr_buf[0]), conn->fd, &real_twr); conn->twr += real_twr; return wr; } static bool conn_has_unsent(tproxy_conn_t *conn) { return conn->wr_unsent || conn_buffers_present(conn); } static int conn_bytes_unread(tproxy_conn_t *conn) { int numbytes=-1; ioctl(conn->fd, FIONREAD, &numbytes); return numbytes; } static bool conn_has_unsent_pair(tproxy_conn_t *conn) { return conn_has_unsent(conn) || (conn_partner_alive(conn) && conn_has_unsent(conn->partner)); } static ssize_t send_or_buffer(send_buffer_t *sb, int fd, const void *buf, size_t len, int flags, int ttl) { ssize_t wr=0; if (len) { wr = send_with_ttl(fd, buf, len, flags, ttl); if (wr<0 && errno==EAGAIN) wr=0; if (wr>=0 && wr=2) { int v; socklen_t sz; sz=sizeof(int); if (!getsockopt(fd,SOL_SOCKET,SO_RCVBUF,&v,&sz)) DBGPRINT("fd=%d SO_RCVBUF=%d",fd,v) sz=sizeof(int); if (!getsockopt(fd,SOL_SOCKET,SO_SNDBUF,&v,&sz)) DBGPRINT("fd=%d SO_SNDBUF=%d",fd,v) } } bool set_socket_buffers(int fd, int rcvbuf, int sndbuf) { DBGPRINT("set_socket_buffers fd=%d rcvbuf=%d sndbuf=%d",fd,rcvbuf,sndbuf) if (rcvbuf && setsockopt(fd, SOL_SOCKET, SO_RCVBUF, &rcvbuf, sizeof(int)) <0) { perror("setsockopt (SO_RCVBUF)"); close(fd); return false; } if (sndbuf && setsockopt(fd, SOL_SOCKET, SO_SNDBUF, &sndbuf, sizeof(int)) <0) { perror("setsockopt (SO_SNDBUF)"); close(fd); return false; } dbgprint_socket_buffers(fd); return true; } static bool proxy_remote_conn_ack(tproxy_conn_t *conn, int sock_err) { // if proxy mode acknowledge connection request // conn = remote. conn->partner = local if (!conn->remote || !conn_partner_alive(conn)) return false; bool bres = true; switch(conn->partner->conn_type) { case CONN_TYPE_SOCKS: if (conn->partner->socks_state==S_WAIT_CONNECTION) { conn->partner->socks_state=S_TCP; bres = socks_send_rep_errno(conn->partner->socks_ver,conn->partner->fd,sock_err); DBGPRINT("socks connection acknowledgement. bres=%d remote_errn=%d remote_fd=%d local_fd=%d",bres,sock_err,conn->fd,conn->partner->fd) } break; } return bres; } //Createas a socket and initiates the connection to the host specified by //remote_addr. //Returns -1 if something fails, >0 on success (socket fd). static int connect_remote(const struct sockaddr *remote_addr, bool bApplyConnectionFooling) { int remote_fd = 0, yes = 1, no = 0, v; if((remote_fd = socket(remote_addr->sa_family, SOCK_STREAM, 0)) < 0) { perror("socket (connect_remote)"); return -1; } // Use NONBLOCK to avoid slow connects affecting the performance of other connections // separate fcntl call to comply with macos if (fcntl(remote_fd, F_SETFL, O_NONBLOCK)<0) { perror("socket set O_NONBLOCK (connect_remote)"); close(remote_fd); return -1; } if (setsockopt(remote_fd, SOL_SOCKET, SO_REUSEADDR, &yes, sizeof(yes)) < 0) { perror("setsockopt (SO_REUSEADDR, connect_remote)"); close(remote_fd); return -1; } if (!set_socket_buffers(remote_fd, params.remote_rcvbuf, params.remote_sndbuf)) return -1; if (!set_keepalive(remote_fd)) { perror("set_keepalive"); close(remote_fd); return -1; } if (setsockopt(remote_fd, IPPROTO_TCP, TCP_NODELAY, params.skip_nodelay ? &no : &yes, sizeof(int)) <0) { perror("setsockopt (TCP_NODELAY, connect_remote)"); close(remote_fd); return -1; } if (bApplyConnectionFooling && params.mss) { uint16_t port = saport(remote_addr); if (pf_in_range(port,¶ms.mss_pf)) { VPRINT("Setting MSS %d",params.mss) if (setsockopt(remote_fd, IPPROTO_TCP, TCP_MAXSEG, ¶ms.mss, sizeof(int)) <0) { perror("setsockopt (TCP_MAXSEG, connect_remote)"); close(remote_fd); return -1; } } else { VPRINT("Not setting MSS. Port %u is out of MSS port range.",port) } } if (connect(remote_fd, remote_addr, remote_addr->sa_family == AF_INET ? sizeof(struct sockaddr_in) : sizeof(struct sockaddr_in6)) < 0) { if(errno != EINPROGRESS) { perror("connect (connect_remote)"); close(remote_fd); return -1; } } DBGPRINT("Connecting remote fd=%d",remote_fd) return remote_fd; } //Free resources occupied by this connection static void free_conn(tproxy_conn_t *conn) { if (!conn) return; if (conn->fd) close(conn->fd); if (conn->splice_pipe[0]) { close(conn->splice_pipe[0]); close(conn->splice_pipe[1]); } conn_free_buffers(conn); if (conn->partner) conn->partner->partner=NULL; if (conn->track.hostname) free(conn->track.hostname); if (conn->socks_ri) conn->socks_ri->ptr = NULL; // detach conn free(conn); } static tproxy_conn_t *new_conn(int fd, bool remote) { tproxy_conn_t *conn; //Create connection object and fill in information if((conn = (tproxy_conn_t*) malloc(sizeof(tproxy_conn_t))) == NULL) { fprintf(stderr, "Could not allocate memory for connection\n"); return NULL; } memset(conn, 0, sizeof(tproxy_conn_t)); conn->state = CONN_UNAVAILABLE; conn->fd = fd; conn->remote = remote; #ifdef SPLICE_PRESENT // if dont tamper - both legs are spliced, create 2 pipes // otherwise create pipe only in local leg if (!params.nosplice && ( !remote || !params.tamper || params.tamper_start || params.tamper_cutoff ) && pipe2(conn->splice_pipe, O_NONBLOCK) != 0) { fprintf(stderr, "Could not create the splice pipe\n"); free_conn(conn); return NULL; } #endif return conn; } static bool epoll_set(tproxy_conn_t *conn, uint32_t events) { struct epoll_event ev; memset(&ev, 0, sizeof(ev)); ev.events = events; ev.data.ptr = (void*) conn; DBGPRINT("epoll_set fd=%d events=%08X",conn->fd,events); if(epoll_ctl(conn->efd, EPOLL_CTL_MOD, conn->fd, &ev)==-1 && epoll_ctl(conn->efd, EPOLL_CTL_ADD, conn->fd, &ev)==-1) { perror("epoll_ctl (add/mod)"); return false; } return true; } static bool epoll_del(tproxy_conn_t *conn) { struct epoll_event ev; memset(&ev, 0, sizeof(ev)); DBGPRINT("epoll_del fd=%d",conn->fd); if(epoll_ctl(conn->efd, EPOLL_CTL_DEL, conn->fd, &ev)==-1) { perror("epoll_ctl (del)"); return false; } return true; } static bool epoll_update_flow(tproxy_conn_t *conn) { if (conn->bFlowInPrev==conn->bFlowIn && conn->bFlowOutPrev==conn->bFlowOut && conn->bPrevRdhup==(conn->state==CONN_RDHUP)) return true; // unchanged, no need to syscall uint32_t evtmask = (conn->state==CONN_RDHUP ? 0 : EPOLLRDHUP)|(conn->bFlowIn?EPOLLIN:0)|(conn->bFlowOut?EPOLLOUT:0); if (!epoll_set(conn, evtmask)) return false; DBGPRINT("SET FLOW fd=%d to in=%d out=%d state_rdhup=%d",conn->fd,conn->bFlowIn,conn->bFlowOut,conn->state==CONN_RDHUP) conn->bFlowInPrev = conn->bFlowIn; conn->bFlowOutPrev = conn->bFlowOut; conn->bPrevRdhup = (conn->state==CONN_RDHUP); return true; } static bool epoll_set_flow(tproxy_conn_t *conn, bool bFlowIn, bool bFlowOut) { conn->bFlowIn = bFlowIn; conn->bFlowOut = bFlowOut; return epoll_update_flow(conn); } //Acquires information, initiates a connect and initialises a new connection //object. Return NULL if anything fails, pointer to object otherwise static tproxy_conn_t* add_tcp_connection(int efd, struct tailhead *conn_list,int local_fd, const struct sockaddr *accept_sa, uint16_t listen_port, conn_type_t proxy_type) { struct sockaddr_storage orig_dst; tproxy_conn_t *conn; int remote_fd=0; if (proxy_type==CONN_TYPE_TRANSPARENT) { if(!get_dest_addr(local_fd, accept_sa, &orig_dst)) { fprintf(stderr, "Could not get destination address\n"); close(local_fd); return NULL; } if (check_local_ip((struct sockaddr*)&orig_dst) && saport((struct sockaddr*)&orig_dst)==listen_port) { VPRINT("Dropping connection to local address to the same port to avoid loop") close(local_fd); return NULL; } } // socket buffers inherited from listen_fd dbgprint_socket_buffers(local_fd); if(!set_keepalive(local_fd)) { perror("set_keepalive"); close(local_fd); return 0; } if (proxy_type==CONN_TYPE_TRANSPARENT) { if ((remote_fd = connect_remote((struct sockaddr *)&orig_dst, true)) < 0) { fprintf(stderr, "Failed to connect\n"); close(local_fd); return NULL; } } if(!(conn = new_conn(local_fd, false))) { if (remote_fd) close(remote_fd); close(local_fd); return NULL; } conn->conn_type = proxy_type; // only local connection has proxy_type. remote is always in tcp mode conn->state = CONN_AVAILABLE; // accepted connection is immediately available conn->efd = efd; if (proxy_type==CONN_TYPE_TRANSPARENT) { if(!(conn->partner = new_conn(remote_fd, true))) { free_conn(conn); close(remote_fd); return NULL; } conn->partner->partner = conn; conn->partner->efd = efd; //remote_fd is connecting. Non-blocking connects are signaled as done by //socket being marked as ready for writing if (!epoll_set(conn->partner, EPOLLOUT)) { free_conn(conn->partner); free_conn(conn); return NULL; } } //Transparent proxy mode : // Local socket can be closed while waiting for connection attempt. I need // to detect this when waiting for connect() to complete. However, I dont // want to get EPOLLIN-events, as I dont want to receive any data before // remote connection is established //Proxy mode : I need to service proxy protocol // remote connection not started until proxy handshake is complete if (!epoll_set(conn, proxy_type==CONN_TYPE_TRANSPARENT ? EPOLLRDHUP : (EPOLLIN|EPOLLRDHUP))) { free_conn(conn->partner); free_conn(conn); return NULL; } TAILQ_INSERT_HEAD(conn_list, conn, conn_ptrs); legs_local++; if (conn->partner) { TAILQ_INSERT_HEAD(conn_list, conn->partner, conn_ptrs); legs_remote++; } return conn; } //Checks if a connection attempt was successful or not //Returns true if successfull, false if not static bool check_connection_attempt(tproxy_conn_t *conn, int efd) { int errn = 0; socklen_t optlen = sizeof(errn); if (conn->state!=CONN_UNAVAILABLE || !conn->remote) { // locals are connected since accept // remote need to be checked only once return true; } // check the connection was sucessfull. it means its not in in SO_ERROR state if(getsockopt(conn->fd, SOL_SOCKET, SO_ERROR, &errn, &optlen) == -1) { perror("getsockopt (SO_ERROR)"); return false; } if (!errn) { VPRINT("Socket fd=%d (remote) connected", conn->fd) if (!epoll_set_flow(conn, true, false) || conn_partner_alive(conn) && !epoll_set_flow(conn->partner, true, false)) { return false; } conn->state = CONN_AVAILABLE; } proxy_remote_conn_ack(conn,get_so_error(conn->fd)); return !errn; } static bool epoll_set_flow_pair(tproxy_conn_t *conn) { bool bHasUnsent = conn_has_unsent(conn); bool bHasUnsentPartner = conn_partner_alive(conn) ? conn_has_unsent(conn->partner) : false; DBGPRINT("epoll_set_flow_pair fd=%d remote=%d partner_fd=%d bHasUnsent=%d bHasUnsentPartner=%d state_rdhup=%d", conn->fd , conn->remote, conn_partner_alive(conn) ? conn->partner->fd : 0, bHasUnsent, bHasUnsentPartner, conn->state==CONN_RDHUP) if (!epoll_set_flow(conn, !bHasUnsentPartner && (conn->state!=CONN_RDHUP), bHasUnsent || conn->state==CONN_RDHUP)) return false; if (conn_partner_alive(conn)) { if (!epoll_set_flow(conn->partner, !bHasUnsent && (conn->partner->state!=CONN_RDHUP), bHasUnsentPartner || conn->partner->state==CONN_RDHUP)) return false; } return true; } static bool handle_unsent(tproxy_conn_t *conn) { ssize_t wr; DBGPRINT("+handle_unsent, fd=%d has_unsent=%d has_unsent_partner=%d",conn->fd,conn_has_unsent(conn),conn_partner_alive(conn) ? conn_has_unsent(conn->partner) : false) #ifdef SPLICE_PRESENT if (!params.nosplice && conn->wr_unsent) { wr = splice(conn->splice_pipe[0], NULL, conn->fd, NULL, conn->wr_unsent, SPLICE_F_MOVE | SPLICE_F_NONBLOCK); DBGPRINT("splice unsent=%zd wr=%zd err=%d",conn->wr_unsent,wr,errno) if (wr<0) { if (errno==EAGAIN) wr=0; else return false; } conn->twr += wr; conn->wr_unsent -= wr; } #endif if (!conn->wr_unsent && conn_buffers_present(conn)) { wr=conn_buffers_send(conn); DBGPRINT("conn_buffers_send wr=%zd",wr) if (wr<0) return false; } return epoll_set_flow_pair(conn); } bool proxy_mode_connect_remote(const struct sockaddr *sa, tproxy_conn_t *conn, struct tailhead *conn_list) { int remote_fd; if (params.debug>=1) { printf("socks target for fd=%d is : ", conn->fd); print_sockaddr(sa); printf("\n"); } if (check_local_ip((struct sockaddr *)sa)) { VPRINT("Dropping connection to local address for security reasons") socks_send_rep(conn->socks_ver, conn->fd, S5_REP_NOT_ALLOWED_BY_RULESET); return false; } bool bConnFooling=true; if (conn->track.hostname && params.mss) { bConnFooling=HostlistCheck(conn->track.hostname, NULL); if (!bConnFooling) VPRINT("0-phase desync hostlist check negative. not acting on this connection.") } if ((remote_fd = connect_remote(sa, bConnFooling)) < 0) { fprintf(stderr, "socks failed to connect (1) errno=%d\n", errno); socks_send_rep_errno(conn->socks_ver, conn->fd, errno); return false; } if (!(conn->partner = new_conn(remote_fd, true))) { close(remote_fd); fprintf(stderr, "socks out-of-memory (1)\n"); socks_send_rep(conn->socks_ver, conn->fd, S5_REP_GENERAL_FAILURE); return false; } conn->partner->partner = conn; conn->partner->efd = conn->efd; if (!epoll_set(conn->partner, EPOLLOUT)) { fprintf(stderr, "socks epoll_set error %d\n", errno); free_conn(conn->partner); conn->partner = NULL; socks_send_rep(conn->socks_ver, conn->fd, S5_REP_GENERAL_FAILURE); return false; } TAILQ_INSERT_HEAD(conn_list, conn->partner, conn_ptrs); legs_remote++; print_legs(); DBGPRINT("S_WAIT_CONNECTION") conn->socks_state = S_WAIT_CONNECTION; return true; } static bool handle_proxy_mode(tproxy_conn_t *conn, struct tailhead *conn_list) { // To simplify things I dont care about buffering. If message splits, I just hang up // in proxy mode messages are short. they can be split only intentionally. all normal programs send them in one packet ssize_t rd,wr; char buf[sizeof(s5_req)]; // s5_req - the largest possible req struct sockaddr_storage ss; // receive proxy control message rd=recv(conn->fd, buf, sizeof(buf), MSG_DONTWAIT); DBGPRINT("handle_proxy_mode rd=%zd",rd) if (rd<1) return false; // hangup switch(conn->conn_type) { case CONN_TYPE_SOCKS: switch(conn->socks_state) { case S_WAIT_HANDSHAKE: DBGPRINT("S_WAIT_HANDSHAKE") if (buf[0] != 5 && buf[0] != 4) return false; // unknown socks version conn->socks_ver = buf[0]; DBGPRINT("socks version %u", conn->socks_ver) if (conn->socks_ver==5) { s5_handshake *m = (s5_handshake*)buf; s5_handshake_ack ack; uint8_t k; ack.ver=5; if (!S5_REQ_HANDHSHAKE_VALID(m,rd)) { DBGPRINT("socks5 proxy handshake invalid") return false; } for (k=0;knmethods;k++) if (m->methods[k]==S5_AUTH_NONE) break; if (k>=m->nmethods) { DBGPRINT("socks5 client wants authentication but we dont support") ack.method=S5_AUTH_UNACCEPTABLE; wr=send(conn->fd,&ack,sizeof(ack),MSG_DONTWAIT); return false; } DBGPRINT("socks5 recv valid handshake") ack.method=S5_AUTH_NONE; wr=send(conn->fd,&ack,sizeof(ack),MSG_DONTWAIT); if (wr!=sizeof(ack)) { DBGPRINT("socks5 handshake ack send error. wr=%zd errno=%d",wr,errno) return false; } DBGPRINT("socks5 send handshake ack OK") conn->socks_state=S_WAIT_REQUEST; return true; } else { // socks4 does not have separate handshake phase. it starts with connect request // ipv6 and domain resolving are not supported s4_req *m = (s4_req*)buf; if (!S4_REQ_HEADER_VALID(m, rd)) { DBGPRINT("socks4 request invalid") return false; } if (m->cmd!=S4_CMD_CONNECT) { // BIND is not supported DBGPRINT("socks4 unsupported command %02X", m->cmd) socks4_send_rep(conn->fd, S4_REP_FAILED); return false; } if (!S4_REQ_CONNECT_VALID(m, rd)) { DBGPRINT("socks4 connect request invalid") socks4_send_rep(conn->fd, S4_REP_FAILED); return false; } if (!m->port) { DBGPRINT("socks4 zero port") socks4_send_rep(conn->fd, S4_REP_FAILED); return false; } if (m->ip==htonl(1)) // special ip 0.0.0.1 { VPRINT("socks4a protocol not supported") socks4_send_rep(conn->fd, S4_REP_FAILED); return false; } ss.ss_family = AF_INET; ((struct sockaddr_in*)&ss)->sin_port = m->port; ((struct sockaddr_in*)&ss)->sin_addr.s_addr = m->ip; return proxy_mode_connect_remote((struct sockaddr *)&ss, conn, conn_list); } break; case S_WAIT_REQUEST: DBGPRINT("S_WAIT_REQUEST") { s5_req *m = (s5_req*)buf; if (!S5_REQ_HEADER_VALID(m,rd)) { DBGPRINT("socks5 request invalid") return false; } if (m->cmd!=S5_CMD_CONNECT) { // BIND and UDP are not supported DBGPRINT("socks5 unsupported command %02X", m->cmd) socks5_send_rep(conn->fd,S5_REP_COMMAND_NOT_SUPPORTED); return false; } if (!S5_REQ_CONNECT_VALID(m,rd)) { DBGPRINT("socks5 connect request invalid") return false; } DBGPRINT("socks5 recv valid connect request") switch(m->atyp) { case S5_ATYP_IP4: ss.ss_family = AF_INET; ((struct sockaddr_in*)&ss)->sin_port = m->d4.port; ((struct sockaddr_in*)&ss)->sin_addr = m->d4.addr; break; case S5_ATYP_IP6: ss.ss_family = AF_INET6; ((struct sockaddr_in6*)&ss)->sin6_port = m->d6.port; ((struct sockaddr_in6*)&ss)->sin6_addr = m->d6.addr; ((struct sockaddr_in6*)&ss)->sin6_flowinfo = 0; ((struct sockaddr_in6*)&ss)->sin6_scope_id = 0; break; case S5_ATYP_DOM: { struct addrinfo *ai,hints; int r; uint16_t port; char sport[6]; if (params.no_resolve) { VPRINT("socks5 hostname resolving disabled") socks5_send_rep(conn->fd,S5_REP_NOT_ALLOWED_BY_RULESET); return false; } port=S5_PORT_FROM_DD(m,rd); if (!port) { VPRINT("socks5 no port is given") socks5_send_rep(conn->fd,S5_REP_HOST_UNREACHABLE); return false; } m->dd.domport[m->dd.len] = 0; DBGPRINT("socks5 queue resolve hostname '%s' port '%u'",m->dd.domport,port) conn->socks_ri = resolver_queue(m->dd.domport,port,conn); if (!conn->socks_ri) { VPRINT("socks5 could not queue resolve item") socks5_send_rep(conn->fd,S5_REP_GENERAL_FAILURE); return false; } conn->socks_state=S_WAIT_RESOLVE; DBGPRINT("S_WAIT_RESOLVE") return true; } break; default: return false; // should not be here. S5_REQ_CONNECT_VALID checks for valid atyp } return proxy_mode_connect_remote((struct sockaddr *)&ss,conn,conn_list); } break; case S_WAIT_RESOLVE: DBGPRINT("socks received message while in S_WAIT_RESOLVE. hanging up") break; case S_WAIT_CONNECTION: DBGPRINT("socks received message while in S_WAIT_CONNECTION. hanging up") break; default: DBGPRINT("socks received message while in an unexpected connection state") break; } break; } return false; } static bool resolve_complete(struct resolve_item *ri, struct tailhead *conn_list) { tproxy_conn_t *conn = (tproxy_conn_t *)ri->ptr; if (conn && (conn->state != CONN_CLOSED)) { if (conn->socks_state==S_WAIT_RESOLVE) { DBGPRINT("resolve_complete %s. getaddrinfo result %d", ri->dom, ri->ga_res); if (ri->ga_res) { socks5_send_rep(conn->fd,S5_REP_HOST_UNREACHABLE); return false;; } else { if (!conn->track.hostname) { DBGPRINT("resolve_complete put hostname : %s", ri->dom) conn->track.hostname = strdup(ri->dom); } return proxy_mode_connect_remote((struct sockaddr *)&ri->ss,conn,conn_list); } } else fprintf(stderr, "resolve_complete: conn in wrong socks_state !!! (%s)\n", ri->dom); } else DBGPRINT("resolve_complete: orphaned resolve for %s", ri->dom); return true; } static bool in_tamper_out_range(tproxy_conn_t *conn) { return (params.tamper_start_n ? (conn->tnrd+1) : conn->trd) >= params.tamper_start && (!params.tamper_cutoff || (params.tamper_cutoff_n ? (conn->tnrd+1) : conn->trd) < params.tamper_cutoff); } static void tamper(tproxy_conn_t *conn, uint8_t *segment, size_t segment_buffer_size, size_t *segment_size, size_t *split_pos, uint8_t *split_flags) { *split_pos=0; if (params.tamper) { if (conn->remote) { if (conn_partner_alive(conn) && !conn->partner->track.bTamperInCutoff) { tamper_in(&conn->partner->track,segment,segment_buffer_size,segment_size); } } else { bool in_range = in_tamper_out_range(conn); DBGPRINT("tamper_out stream pos %" PRIu64 "(n%" PRIu64 "). tamper range %s%u-%s%u (%s)", conn->trd, conn->tnrd+1, params.tamper_start_n ? "n" : "" , params.tamper_start, params.tamper_cutoff_n ? "n" : "" , params.tamper_cutoff, in_range ? "IN RANGE" : "OUT OF RANGE") if (in_range) tamper_out(&conn->track,segment,segment_buffer_size,segment_size,split_pos,split_flags); } } } // buffer must have at least one extra byte for OOB static ssize_t send_or_buffer_oob(send_buffer_t *sb, int fd, uint8_t *buf, size_t len, int ttl, bool oob) { ssize_t wr; if (oob) { VPRINT("Sending OOB byte %02X", params.oob_byte) uint8_t oob_save; oob_save = buf[len]; buf[len] = params.oob_byte; wr = send_or_buffer(sb, fd, buf, len+1, MSG_OOB, ttl); buf[len] = oob_save; } else wr = send_or_buffer(sb, fd, buf, len, 0, ttl); return wr; } #define RD_BLOCK_SIZE 65536 #define MAX_WASTE (1024*1024) static bool handle_epoll(tproxy_conn_t *conn, struct tailhead *conn_list, uint32_t evt) { int numbytes; ssize_t rd = 0, wr = 0; size_t bs; DBGPRINT("+handle_epoll") if (!conn_in_tcp_mode(conn)) { if (!(evt & EPOLLIN)) return true; // nothing to read return handle_proxy_mode(conn,conn_list); } if (!handle_unsent(conn)) return false; // error if (!conn_partner_alive(conn) && !conn_has_unsent(conn)) return false; // when no partner, we only waste read and send unsent if (!(evt & EPOLLIN)) return true; // nothing to read if (!conn_partner_alive(conn)) { // throw it to a black hole uint8_t waste[65070]; uint64_t trd=0; while((rd=recv(conn->fd, waste, sizeof(waste), MSG_DONTWAIT))>0 && trdtrd+=rd; } DBGPRINT("wasted recv=%zd all_rd=%" PRIu64 " err=%d",rd,trd,errno) return true; } // do not receive new until old is sent if (conn_has_unsent(conn->partner)) return true; bool oom=false; numbytes=conn_bytes_unread(conn); DBGPRINT("numbytes=%d",numbytes) if (numbytes>0) { DBGPRINT("%s leg fd=%d stream pos : %" PRIu64 "(n%" PRIu64 ")/%" PRIu64, conn->remote ? "remote" : "local", conn->fd, conn->trd,conn->tnrd+1,conn->twr) #ifdef SPLICE_PRESENT if (!params.nosplice && (!params.tamper || conn->remote && conn->partner->track.bTamperInCutoff || !conn->remote && !in_tamper_out_range(conn))) { // incoming data from remote leg we splice without touching // pipe is in the local leg, so its in conn->partner->splice_pipe // if we dont tamper - splice both legs rd = splice(conn->fd, NULL, conn->partner->splice_pipe[1], NULL, SPLICE_LEN, SPLICE_F_MOVE | SPLICE_F_NONBLOCK); DBGPRINT("splice fd=%d remote=%d len=%d rd=%zd err=%d",conn->fd,conn->remote,SPLICE_LEN,rd,errno) if (rd<0 && errno==EAGAIN) rd=0; if (rd>0) { conn->tnrd++; conn->trd += rd; conn->partner->wr_unsent += rd; wr = splice(conn->partner->splice_pipe[0], NULL, conn->partner->fd, NULL, conn->partner->wr_unsent, SPLICE_F_MOVE | SPLICE_F_NONBLOCK); DBGPRINT("splice fd=%d remote=%d wr=%zd err=%d",conn->partner->fd,conn->partner->remote,wr,errno) if (wr<0 && errno==EAGAIN) wr=0; if (wr>0) { conn->partner->wr_unsent -= wr; conn->partner->twr += wr; } } } else #endif { // incoming data from local leg uint8_t buf[RD_BLOCK_SIZE + 5]; rd = recv(conn->fd, buf, RD_BLOCK_SIZE, MSG_DONTWAIT); DBGPRINT("recv fd=%d rd=%zd err=%d",conn->fd, rd,errno) if (rd<0 && errno==EAGAIN) rd=0; if (rd>0) { size_t split_pos; uint8_t split_flags; bs = rd; // tamper needs to know stream position of the block start tamper(conn, buf, sizeof(buf), &bs, &split_pos, &split_flags); // increase after tamper conn->tnrd++; conn->trd+=rd; if (split_pos && bspartner->wr_buf, conn->partner->fd, buf, split_pos, !!(split_flags & SPLIT_FLAG_DISORDER), !!(split_flags & SPLIT_FLAG_OOB)); DBGPRINT("send_or_buffer(1) fd=%d wr=%zd err=%d",conn->partner->fd,wr,errno) if (wr >= 0) { conn->partner->twr += wr; wr = send_or_buffer(conn->partner->wr_buf + 1, conn->partner->fd, buf + split_pos, bs - split_pos, 0, 0); DBGPRINT("send_or_buffer(2) fd=%d wr=%zd err=%d",conn->partner->fd,wr,errno) if (wr>0) conn->partner->twr += wr; } } else { wr = send_or_buffer(conn->partner->wr_buf, conn->partner->fd, buf, bs, 0, 0); DBGPRINT("send_or_buffer(3) fd=%d wr=%zd err=%d",conn->partner->fd,wr,errno) if (wr>0) conn->partner->twr += wr; } if (wr<0 && errno==ENOMEM) oom=true; } } if (!epoll_set_flow_pair(conn)) return false; } DBGPRINT("-handle_epoll rd=%zd wr=%zd",rd,wr) if (oom) DBGPRINT("handle_epoll: OUT_OF_MEMORY") // do not fail if partner fails. // if partner fails there will be another epoll event with EPOLLHUP or EPOLLERR return rd>=0 && !oom; } static bool remove_closed_connections(int efd, struct tailhead *close_list) { tproxy_conn_t *conn = NULL; bool bRemoved = false; while ((conn = TAILQ_FIRST(close_list))) { TAILQ_REMOVE(close_list, conn, conn_ptrs); shutdown(conn->fd,SHUT_RDWR); epoll_del(conn); VPRINT("Socket fd=%d (partner_fd=%d, remote=%d) closed, connection removed. total_read=%" PRIu64 " total_write=%" PRIu64 " event_count=%u", conn->fd, conn->partner ? conn->partner->fd : 0, conn->remote, conn->trd, conn->twr, conn->event_count) if (conn->remote) legs_remote--; else legs_local--; free_conn(conn); bRemoved = true; } return bRemoved; } // move to close list connection and its partner static void close_tcp_conn(struct tailhead *conn_list, struct tailhead *close_list, tproxy_conn_t *conn) { if (conn->state != CONN_CLOSED) { conn->state = CONN_CLOSED; TAILQ_REMOVE(conn_list, conn, conn_ptrs); TAILQ_INSERT_TAIL(close_list, conn, conn_ptrs); } } static bool read_all_and_buffer(tproxy_conn_t *conn, int buffer_number) { if (conn_partner_alive(conn)) { int numbytes=conn_bytes_unread(conn); DBGPRINT("read_all_and_buffer(%d) numbytes=%d",buffer_number,numbytes) if (numbytes>0) { if (send_buffer_create(conn->partner->wr_buf+buffer_number, NULL, numbytes, 5, 0, 0)) { ssize_t rd = recv(conn->fd, conn->partner->wr_buf[buffer_number].data, numbytes, MSG_DONTWAIT); if (rd>0) { conn->trd+=rd; conn->partner->wr_buf[buffer_number].len = rd; conn->partner->bFlowOut = true; size_t split_pos; uint8_t split_flags; tamper(conn, conn->partner->wr_buf[buffer_number].data, numbytes+5, &conn->partner->wr_buf[buffer_number].len, &split_pos, &split_flags); if (epoll_update_flow(conn->partner)) return true; } send_buffer_free(conn->partner->wr_buf+buffer_number); } } } return false; } static bool conn_timed_out(tproxy_conn_t *conn) { if (conn->orphan_since && conn->state==CONN_UNAVAILABLE) { time_t timediff = time(NULL) - conn->orphan_since; return timediff>=params.max_orphan_time; } else return false; } static void conn_close_timed_out(struct tailhead *conn_list, struct tailhead *close_list) { tproxy_conn_t *c,*cnext = NULL; DBGPRINT("conn_close_timed_out") c = TAILQ_FIRST(conn_list); while(c) { cnext = TAILQ_NEXT(c,conn_ptrs); if (conn_timed_out(c)) { DBGPRINT("closing timed out connection: fd=%d remote=%d",c->fd,c->remote) close_tcp_conn(conn_list,close_list,c); } c = cnext; } } static void conn_close_both(struct tailhead *conn_list, struct tailhead *close_list, tproxy_conn_t *conn) { if (conn_partner_alive(conn)) close_tcp_conn(conn_list,close_list,conn->partner); close_tcp_conn(conn_list,close_list,conn); } static void conn_close_with_partner_check(struct tailhead *conn_list, struct tailhead *close_list, tproxy_conn_t *conn) { close_tcp_conn(conn_list,close_list,conn); if (conn_partner_alive(conn)) { if (!conn_has_unsent(conn->partner)) close_tcp_conn(conn_list,close_list,conn->partner); else if (conn->partner->remote && conn->partner->state==CONN_UNAVAILABLE && params.max_orphan_time) // time out only remote legs that are not connected yet conn->partner->orphan_since = time(NULL); } } static bool handle_resolve_pipe(tproxy_conn_t **conn, struct tailhead *conn_list, int fd) { ssize_t rd; struct resolve_item *ri; bool b; rd = read(fd,&ri,sizeof(void*)); if (rd<0) { perror("resolve_pipe read"); return false; } else if (rd!=sizeof(void*)) { // partial pointer read is FATAL. in any case it will cause pointer corruption and coredump fprintf(stderr,"resolve_pipe not full read %zu\n",rd); exit(1000); } b = resolve_complete(ri, conn_list); *conn = (tproxy_conn_t *)ri->ptr; if (*conn) (*conn)->socks_ri = NULL; free(ri); return b; } int event_loop(const int *listen_fd, size_t listen_fd_ct) { int retval = 0, num_events = 0; int tmp_fd = 0; //Used to temporarily hold the accepted file descriptor tproxy_conn_t *conn = NULL; int efd=0, i; struct epoll_event ev, events[MAX_EPOLL_EVENTS]; struct tailhead conn_list, close_list; time_t tm,last_timeout_check=0; tproxy_conn_t *listen_conn = NULL; size_t sct; struct sockaddr_storage accept_sa; socklen_t accept_salen; int resolve_pipe[2]; if (!listen_fd_ct) return -1; resolve_pipe[0]=resolve_pipe[1]=0; legs_local = legs_remote = 0; //Initialize queue (remember that TAILQ_HEAD just defines the struct) TAILQ_INIT(&conn_list); TAILQ_INIT(&close_list); if ((efd = epoll_create(1)) == -1) { perror("epoll_create"); return -1; } if (!(listen_conn=calloc(listen_fd_ct,sizeof(*listen_conn)))) { perror("calloc listen_conn"); return -1; } //Start monitoring listen sockets memset(&ev, 0, sizeof(ev)); ev.events = EPOLLIN; for(sct=0;sctevent_count++; if (conn->listener) { DBGPRINT("\nEVENT mask %08X fd=%d accept",events[i].events,conn->fd) accept_salen = sizeof(accept_sa); //Accept new connection #if defined (__APPLE__) // macos does not have accept4() tmp_fd = accept(conn->fd, (struct sockaddr*)&accept_sa, &accept_salen); #else tmp_fd = accept4(conn->fd, (struct sockaddr*)&accept_sa, &accept_salen, SOCK_NONBLOCK); #endif if (tmp_fd < 0) { perror("Failed to accept connection"); } else if (legs_local >= params.maxconn) // each connection has 2 legs - local and remote { close(tmp_fd); VPRINT("Too many local legs : %d", legs_local) } #if defined (__APPLE__) // separate fcntl call to comply with macos else if (fcntl(tmp_fd, F_SETFL, O_NONBLOCK) < 0) { perror("socket set O_NONBLOCK (accept)"); close(tmp_fd); } #endif else if (!(conn=add_tcp_connection(efd, &conn_list, tmp_fd, (struct sockaddr*)&accept_sa, params.port, params.proxy_type))) { // add_tcp_connection closes fd in case of failure VPRINT("Failed to add connection"); } else { print_legs(); VPRINT("Socket fd=%d (local) connected", conn->fd) } } else { DBGPRINT("\nEVENT mask %08X fd=%d remote=%d fd_partner=%d",events[i].events,conn->fd,conn->remote,conn_partner_alive(conn) ? conn->partner->fd : 0) if (conn->state != CONN_CLOSED) { if (events[i].events & (EPOLLHUP|EPOLLERR)) { int errn = get_so_error(conn->fd); const char *se; switch (events[i].events & (EPOLLHUP|EPOLLERR)) { case EPOLLERR: se="EPOLLERR"; break; case EPOLLHUP: se="EPOLLHUP"; break; case EPOLLHUP|EPOLLERR: se="EPOLLERR EPOLLHUP"; break; default: se=NULL; } VPRINT("Socket fd=%d (partner_fd=%d, remote=%d) %s so_error=%d (%s)",conn->fd,conn->partner ? conn->partner->fd : 0,conn->remote,se,errn,strerror(errn)); proxy_remote_conn_ack(conn,errn); read_all_and_buffer(conn,3); if (errn==ECONNRESET && conn->remote && params.tamper && conn_partner_alive(conn)) rst_in(&conn->partner->track); conn_close_with_partner_check(&conn_list,&close_list,conn); continue; } if (events[i].events & EPOLLOUT) { if (!check_connection_attempt(conn, efd)) { VPRINT("Connection attempt failed for fd=%d", conn->fd) conn_close_both(&conn_list,&close_list,conn); continue; } } if (events[i].events & EPOLLRDHUP) { DBGPRINT("EPOLLRDHUP") read_all_and_buffer(conn,2); if (!conn->remote && params.tamper) hup_out(&conn->track); if (conn_has_unsent(conn)) { DBGPRINT("conn fd=%d has unsent, not closing", conn->fd) conn->state = CONN_RDHUP; // only writes epoll_set_flow(conn,false,true); } else { DBGPRINT("conn fd=%d has no unsent, closing", conn->fd) conn_close_with_partner_check(&conn_list,&close_list,conn); } continue; } if (events[i].events & (EPOLLIN|EPOLLOUT)) { // will not receive this until successful check_connection_attempt() if (!handle_epoll(conn, &conn_list, events[i].events)) { DBGPRINT("handle_epoll false") conn_close_with_partner_check(&conn_list,&close_list,conn); continue; } } } } } tm = time(NULL); if (last_timeout_check!=tm) { // limit whole list lookups to once per second last_timeout_check=tm; conn_close_timed_out(&conn_list,&close_list); } if (remove_closed_connections(efd, &close_list)) { // at least one leg was removed. recount legs print_legs(); } fflush(stderr); fflush(stdout); // for console messages } ex: if (efd) close(efd); if (listen_conn) free(listen_conn); resolver_deinit(); if (resolve_pipe[0]) close(resolve_pipe[0]); if (resolve_pipe[1]) close(resolve_pipe[1]); return retval; }