Esempio n. 1
0
int do_eventsel_loop(HANDLE other_event)
{
	int n, nhandles, nallhandles, netindex, otherindex;
	long next, ticks;
	HANDLE *handles;
	SOCKET *sklist;
	int skcount;
	long now = GETTICKCOUNT();
	static int timeoutCount = 0;

	if (sk_isClosed()) {
		return -1;
	}

	if (run_timers(now, &next)) {
		ticks = next - GETTICKCOUNT();
		if (ticks < 0) ticks = 0;  /* just in case */
	} else {
		ticks = INFINITE;
	}

	if (ticks < 0 || ticks > 100) ticks = 100;

	handles = handle_get_events(&nhandles);
	handles = sresize(handles, nhandles+2, HANDLE);
	nallhandles = nhandles;

	if (netevent != INVALID_HANDLE_VALUE)
		handles[netindex = nallhandles++] = netevent;
	else
		netindex = -1;
	if (other_event != INVALID_HANDLE_VALUE)
		handles[otherindex = nallhandles++] = other_event;
	else
		otherindex = -1;

	n = WaitForMultipleObjects(nallhandles, handles, FALSE, ticks);

	if (STATUS_TIMEOUT == n) {
		sfree(handles);
		++timeoutCount;
		return timeoutCount > 50 ? -1 : 0;
	}
	timeoutCount = 0;

	if ((unsigned)(n - WAIT_OBJECT_0) < (unsigned)nhandles) {
		handle_got_event(handles[n - WAIT_OBJECT_0]);
	} else if (netindex >= 0 && n == WAIT_OBJECT_0 + netindex) {
		WSANETWORKEVENTS things;
		SOCKET socket;
		extern SOCKET first_socket(int *), next_socket(int *);
		extern int select_result(WPARAM, LPARAM);
		int i, socketstate;

		/*
		* We must not call select_result() for any socket
		* until we have finished enumerating within the
		* tree. This is because select_result() may close
		* the socket and modify the tree.
		*/
		/* Count the active sockets. */
		i = 0;		
		for (socket = first_socket(&socketstate);
			socket != INVALID_SOCKET;
			socket = next_socket(&socketstate)) i++;

		/* Expand the buffer if necessary. */
		sklist = snewn(i, SOCKET);

		/* Retrieve the sockets into sklist. */
		skcount = 0;
		for (socket = first_socket(&socketstate);
			socket != INVALID_SOCKET;
			socket = next_socket(&socketstate)) {
				sklist[skcount++] = socket;
		}

		/* Now we're done enumerating; go through the list. */
		for (i = 0; i < skcount; i++) {
			WPARAM wp;
			socket = sklist[i];
			wp = (WPARAM) socket;
			if (!p_WSAEnumNetworkEvents(socket, NULL, &things)) {
				static const struct { int bit, mask; } eventtypes[] = {
					{FD_CONNECT_BIT, FD_CONNECT},
					{FD_READ_BIT, FD_READ},
					{FD_CLOSE_BIT, FD_CLOSE},
					{FD_OOB_BIT, FD_OOB},
					{FD_WRITE_BIT, FD_WRITE},
					{FD_ACCEPT_BIT, FD_ACCEPT},
				};
				int e;

				noise_ultralight(socket);
				noise_ultralight(things.lNetworkEvents);

				for (e = 0; e < lenof(eventtypes); e++)
					if (things.lNetworkEvents & eventtypes[e].mask) {
						LPARAM lp;
						int err = things.iErrorCode[eventtypes[e].bit];
						lp = WSAMAKESELECTREPLY(eventtypes[e].mask, err);
						select_result(wp, lp);
					}
			}
		}

		sfree(sklist);
	}

	sfree(handles);

	if (n == WAIT_TIMEOUT) {
		now = next;
	} else {
		now = GETTICKCOUNT();
	}

	if (otherindex >= 0 && n == WAIT_OBJECT_0 + otherindex)
		return 1;

	return 0;
}
Esempio n. 2
0
int main(int argc, char **argv)
{
    bool sending;
    SOCKET *sklist;
    size_t skcount, sksize;
    int exitcode;
    bool errors;
    bool use_subsystem = false;
    bool just_test_share_exists = false;
    enum TriState sanitise_stdout = AUTO, sanitise_stderr = AUTO;
    unsigned long now, next, then;
    const struct BackendVtable *vt;

    dll_hijacking_protection();

    sklist = NULL;
    skcount = sksize = 0;
    /*
     * Initialise port and protocol to sensible defaults. (These
     * will be overridden by more or less anything.)
     */
    default_protocol = PROT_SSH;
    default_port = 22;

    flags = 0;
    cmdline_tooltype |=
        (TOOLTYPE_HOST_ARG |
         TOOLTYPE_HOST_ARG_CAN_BE_SESSION |
         TOOLTYPE_HOST_ARG_PROTOCOL_PREFIX |
         TOOLTYPE_HOST_ARG_FROM_LAUNCHABLE_LOAD);

    /*
     * Process the command line.
     */
    conf = conf_new();
    do_defaults(NULL, conf);
    loaded_session = false;
    default_protocol = conf_get_int(conf, CONF_protocol);
    default_port = conf_get_int(conf, CONF_port);
    errors = false;
    {
	/*
	 * Override the default protocol if PLINK_PROTOCOL is set.
	 */
	char *p = getenv("PLINK_PROTOCOL");
	if (p) {
            const struct BackendVtable *vt = backend_vt_from_name(p);
            if (vt) {
                default_protocol = vt->protocol;
                default_port = vt->default_port;
		conf_set_int(conf, CONF_protocol, default_protocol);
		conf_set_int(conf, CONF_port, default_port);
	    }
	}
    }
    while (--argc) {
	char *p = *++argv;
        int ret = cmdline_process_param(p, (argc > 1 ? argv[1] : NULL),
                                        1, conf);
        if (ret == -2) {
            fprintf(stderr,
                    "plink: option \"%s\" requires an argument\n", p);
            errors = true;
        } else if (ret == 2) {
            --argc, ++argv;
        } else if (ret == 1) {
            continue;
        } else if (!strcmp(p, "-batch")) {
            console_batch_mode = true;
        } else if (!strcmp(p, "-s")) {
            /* Save status to write to conf later. */
            use_subsystem = true;
        } else if (!strcmp(p, "-V") || !strcmp(p, "--version")) {
            version();
        } else if (!strcmp(p, "--help")) {
            usage();
        } else if (!strcmp(p, "-pgpfp")) {
            pgp_fingerprints();
            exit(1);
        } else if (!strcmp(p, "-shareexists")) {
            just_test_share_exists = true;
        } else if (!strcmp(p, "-sanitise-stdout") ||
                   !strcmp(p, "-sanitize-stdout")) {
            sanitise_stdout = FORCE_ON;
        } else if (!strcmp(p, "-no-sanitise-stdout") ||
                   !strcmp(p, "-no-sanitize-stdout")) {
            sanitise_stdout = FORCE_OFF;
        } else if (!strcmp(p, "-sanitise-stderr") ||
                   !strcmp(p, "-sanitize-stderr")) {
            sanitise_stderr = FORCE_ON;
        } else if (!strcmp(p, "-no-sanitise-stderr") ||
                   !strcmp(p, "-no-sanitize-stderr")) {
            sanitise_stderr = FORCE_OFF;
        } else if (!strcmp(p, "-no-antispoof")) {
            console_antispoof_prompt = false;
	} else if (*p != '-') {
            strbuf *cmdbuf = strbuf_new();

            while (argc > 0) {
                if (cmdbuf->len > 0)
                    put_byte(cmdbuf, ' '); /* add space separator */
                put_datapl(cmdbuf, ptrlen_from_asciz(p));
                if (--argc > 0)
                    p = *++argv;
            }

            conf_set_str(conf, CONF_remote_cmd, cmdbuf->s);
            conf_set_str(conf, CONF_remote_cmd2, "");
            conf_set_bool(conf, CONF_nopty, true);  /* command => no tty */

            strbuf_free(cmdbuf);
            break;		       /* done with cmdline */
        } else {
            fprintf(stderr, "plink: unknown option \"%s\"\n", p);
            errors = true;
        }
    }

    if (errors)
	return 1;

    if (!cmdline_host_ok(conf)) {
	usage();
    }

    prepare_session(conf);

    /*
     * Perform command-line overrides on session configuration.
     */
    cmdline_run_saved(conf);

    /*
     * Apply subsystem status.
     */
    if (use_subsystem)
        conf_set_bool(conf, CONF_ssh_subsys, true);

    if (!*conf_get_str(conf, CONF_remote_cmd) &&
	!*conf_get_str(conf, CONF_remote_cmd2) &&
	!*conf_get_str(conf, CONF_ssh_nc_host))
	flags |= FLAG_INTERACTIVE;

    /*
     * Select protocol. This is farmed out into a table in a
     * separate file to enable an ssh-free variant.
     */
    vt = backend_vt_from_proto(conf_get_int(conf, CONF_protocol));
    if (vt == NULL) {
	fprintf(stderr,
		"Internal fault: Unsupported protocol found\n");
	return 1;
    }

    sk_init();
    if (p_WSAEventSelect == NULL) {
	fprintf(stderr, "Plink requires WinSock 2\n");
	return 1;
    }

    /*
     * Plink doesn't provide any way to add forwardings after the
     * connection is set up, so if there are none now, we can safely set
     * the "simple" flag.
     */
    if (conf_get_int(conf, CONF_protocol) == PROT_SSH &&
	!conf_get_bool(conf, CONF_x11_forward) &&
	!conf_get_bool(conf, CONF_agentfwd) &&
	!conf_get_str_nthstrkey(conf, CONF_portfwd, 0))
	conf_set_bool(conf, CONF_ssh_simple, true);

    logctx = log_init(default_logpolicy, conf);

    if (just_test_share_exists) {
        if (!vt->test_for_upstream) {
            fprintf(stderr, "Connection sharing not supported for connection "
                    "type '%s'\n", vt->name);
            return 1;
        }
        if (vt->test_for_upstream(conf_get_str(conf, CONF_host),
                                  conf_get_int(conf, CONF_port), conf))
            return 0;
        else
            return 1;
    }

    if (restricted_acl) {
        lp_eventlog(default_logpolicy, "Running with restricted process ACL");
    }

    /*
     * Start up the connection.
     */
    netevent = CreateEvent(NULL, false, false, NULL);
    {
	const char *error;
	char *realhost;
	/* nodelay is only useful if stdin is a character device (console) */
	bool nodelay = conf_get_bool(conf, CONF_tcp_nodelay) &&
	    (GetFileType(GetStdHandle(STD_INPUT_HANDLE)) == FILE_TYPE_CHAR);

        error = backend_init(vt, plink_seat, &backend, logctx, conf,
                             conf_get_str(conf, CONF_host),
                             conf_get_int(conf, CONF_port),
                             &realhost, nodelay,
                             conf_get_bool(conf, CONF_tcp_keepalives));
	if (error) {
	    fprintf(stderr, "Unable to open connection:\n%s", error);
	    return 1;
	}
	sfree(realhost);
    }

    inhandle = GetStdHandle(STD_INPUT_HANDLE);
    outhandle = GetStdHandle(STD_OUTPUT_HANDLE);
    errhandle = GetStdHandle(STD_ERROR_HANDLE);

    /*
     * Turn off ECHO and LINE input modes. We don't care if this
     * call fails, because we know we aren't necessarily running in
     * a console.
     */
    GetConsoleMode(inhandle, &orig_console_mode);
    SetConsoleMode(inhandle, ENABLE_PROCESSED_INPUT);

    /*
     * Pass the output handles to the handle-handling subsystem.
     * (The input one we leave until we're through the
     * authentication process.)
     */
    stdout_handle = handle_output_new(outhandle, stdouterr_sent, NULL, 0);
    stderr_handle = handle_output_new(errhandle, stdouterr_sent, NULL, 0);
    handle_sink_init(&stdout_hs, stdout_handle);
    handle_sink_init(&stderr_hs, stderr_handle);
    stdout_bs = BinarySink_UPCAST(&stdout_hs);
    stderr_bs = BinarySink_UPCAST(&stderr_hs);

    /*
     * Decide whether to sanitise control sequences out of standard
     * output and standard error.
     *
     * If we weren't given a command-line override, we do this if (a)
     * the fd in question is pointing at a console, and (b) we aren't
     * trying to allocate a terminal as part of the session.
     *
     * (Rationale: the risk of control sequences is that they cause
     * confusion when sent to a local console, so if there isn't one,
     * no problem. Also, if we allocate a remote terminal, then we
     * sent a terminal type, i.e. we told it what kind of escape
     * sequences we _like_, i.e. we were expecting to receive some.)
     */
    if (sanitise_stdout == FORCE_ON ||
        (sanitise_stdout == AUTO && is_console_handle(outhandle) &&
         conf_get_bool(conf, CONF_nopty))) {
        stdout_scc = stripctrl_new(stdout_bs, true, L'\0');
        stdout_bs = BinarySink_UPCAST(stdout_scc);
    }
    if (sanitise_stderr == FORCE_ON ||
        (sanitise_stderr == AUTO && is_console_handle(errhandle) &&
         conf_get_bool(conf, CONF_nopty))) {
        stderr_scc = stripctrl_new(stderr_bs, true, L'\0');
        stderr_bs = BinarySink_UPCAST(stderr_scc);
    }

    main_thread_id = GetCurrentThreadId();

    sending = false;

    now = GETTICKCOUNT();

    while (1) {
	int nhandles;
	HANDLE *handles;	
	int n;
	DWORD ticks;

        if (!sending && backend_sendok(backend)) {
	    stdin_handle = handle_input_new(inhandle, stdin_gotdata, NULL,
					    0);
	    sending = true;
	}

        if (toplevel_callback_pending()) {
            ticks = 0;
            next = now;
        } else if (run_timers(now, &next)) {
	    then = now;
	    now = GETTICKCOUNT();
	    if (now - then > next - then)
		ticks = 0;
	    else
		ticks = next - now;
	} else {
	    ticks = INFINITE;
            /* no need to initialise next here because we can never
             * get WAIT_TIMEOUT */
	}

	handles = handle_get_events(&nhandles);
	handles = sresize(handles, nhandles+1, HANDLE);
	handles[nhandles] = netevent;
	n = MsgWaitForMultipleObjects(nhandles+1, handles, false, ticks,
				      QS_POSTMESSAGE);
	if ((unsigned)(n - WAIT_OBJECT_0) < (unsigned)nhandles) {
	    handle_got_event(handles[n - WAIT_OBJECT_0]);
	} else if (n == WAIT_OBJECT_0 + nhandles) {
	    WSANETWORKEVENTS things;
	    SOCKET socket;
	    int i, socketstate;

	    /*
	     * We must not call select_result() for any socket
	     * until we have finished enumerating within the tree.
	     * This is because select_result() may close the socket
	     * and modify the tree.
	     */
	    /* Count the active sockets. */
	    i = 0;
	    for (socket = first_socket(&socketstate);
		 socket != INVALID_SOCKET;
		 socket = next_socket(&socketstate)) i++;

	    /* Expand the buffer if necessary. */
            sgrowarray(sklist, sksize, i);

	    /* Retrieve the sockets into sklist. */
	    skcount = 0;
	    for (socket = first_socket(&socketstate);
		 socket != INVALID_SOCKET;
		 socket = next_socket(&socketstate)) {
		sklist[skcount++] = socket;
	    }

	    /* Now we're done enumerating; go through the list. */
	    for (i = 0; i < skcount; i++) {
		WPARAM wp;
		socket = sklist[i];
		wp = (WPARAM) socket;
		if (!p_WSAEnumNetworkEvents(socket, NULL, &things)) {
                    static const struct { int bit, mask; } eventtypes[] = {
                        {FD_CONNECT_BIT, FD_CONNECT},
                        {FD_READ_BIT, FD_READ},
                        {FD_CLOSE_BIT, FD_CLOSE},
                        {FD_OOB_BIT, FD_OOB},
                        {FD_WRITE_BIT, FD_WRITE},
                        {FD_ACCEPT_BIT, FD_ACCEPT},
                    };
                    int e;

		    noise_ultralight(NOISE_SOURCE_IOID, socket);

                    for (e = 0; e < lenof(eventtypes); e++)
                        if (things.lNetworkEvents & eventtypes[e].mask) {
                            LPARAM lp;
                            int err = things.iErrorCode[eventtypes[e].bit];
                            lp = WSAMAKESELECTREPLY(eventtypes[e].mask, err);
                            select_result(wp, lp);
                        }
		}
	    }
	} else if (n == WAIT_OBJECT_0 + nhandles + 1) {
	    MSG msg;
	    while (PeekMessage(&msg, INVALID_HANDLE_VALUE,
			       WM_AGENT_CALLBACK, WM_AGENT_CALLBACK,
			       PM_REMOVE)) {
		struct agent_callback *c = (struct agent_callback *)msg.lParam;
		c->callback(c->callback_ctx, c->data, c->len);
		sfree(c);
	    }
	}

        run_toplevel_callbacks();

	if (n == WAIT_TIMEOUT) {
	    now = next;
	} else {
	    now = GETTICKCOUNT();
	}

	sfree(handles);

	if (sending)
            handle_unthrottle(stdin_handle, backend_sendbuffer(backend));

        if (!backend_connected(backend) &&
	    handle_backlog(stdout_handle) + handle_backlog(stderr_handle) == 0)
	    break;		       /* we closed the connection */
    }
    exitcode = backend_exitcode(backend);
    if (exitcode < 0) {
	fprintf(stderr, "Remote process exit code unavailable\n");
	exitcode = 1;		       /* this is an error condition */
    }
    cleanup_exit(exitcode);
    return 0;			       /* placate compiler warning */
}