/* * OpenVPN -- An application to securely tunnel IP networks * over a single TCP/UDP port, with support for SSL/TLS-based * session authentication and key exchange, * packet encryption, packet authentication, and * packet compression. * * Copyright (C) 2002-2008 OpenVPN Technologies, Inc. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 * as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program (see the file COPYING included with this * distribution); if not, write to the Free Software Foundation, Inc., * 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ /* * These routines are designed to catch replay attacks, * where a man-in-the-middle captures packets and then * attempts to replay them back later. * * We use the "sliding-window" algorithm, similar * to IPSec. */ #include "syshead.h" #ifdef USE_CRYPTO #include "packet_id.h" #include "misc.h" #include "integer.h" #include "memdbg.h" /* * Special time_t value that indicates that * sequence number has expired. */ #define SEQ_UNSEEN ((time_t)0) #define SEQ_EXPIRED ((time_t)1) void packet_id_init (struct packet_id *p, int seq_backtrack, int time_backtrack) { dmsg (D_PID_DEBUG_LOW, "PID packet_id_init seq_backtrack=%d time_backtrack=%d", seq_backtrack, time_backtrack); ASSERT (p); CLEAR (*p); if (seq_backtrack) { ASSERT (MIN_SEQ_BACKTRACK <= seq_backtrack && seq_backtrack <= MAX_SEQ_BACKTRACK); ASSERT (MIN_TIME_BACKTRACK <= time_backtrack && time_backtrack <= MAX_TIME_BACKTRACK); CIRC_LIST_ALLOC (p->rec.seq_list, struct seq_list, seq_backtrack); p->rec.seq_backtrack = seq_backtrack; p->rec.time_backtrack = time_backtrack; } p->rec.initialized = true; } void packet_id_free (struct packet_id *p) { if (p) { dmsg (D_PID_DEBUG_LOW, "PID packet_id_free"); if (p->rec.seq_list) free (p->rec.seq_list); CLEAR (*p); } } void packet_id_add (struct packet_id_rec *p, const struct packet_id_net *pin) { const time_t local_now = now; if (p->seq_list) { packet_id_type diff; /* * If time value increases, start a new * sequence number sequence. */ if (!CIRC_LIST_SIZE (p->seq_list) || pin->time > p->time || (pin->id >= (packet_id_type)p->seq_backtrack && pin->id - (packet_id_type)p->seq_backtrack > p->id)) { p->time = pin->time; p->id = 0; if (pin->id > (packet_id_type)p->seq_backtrack) p->id = pin->id - (packet_id_type)p->seq_backtrack; CIRC_LIST_RESET (p->seq_list); } while (p->id < pin->id) { CIRC_LIST_PUSH (p->seq_list, SEQ_UNSEEN); ++p->id; } diff = p->id - pin->id; if (diff < (packet_id_type) CIRC_LIST_SIZE (p->seq_list) && local_now > SEQ_EXPIRED) CIRC_LIST_ITEM (p->seq_list, diff) = local_now; } else { p->time = pin->time; p->id = pin->id; } } /* * Expire sequence numbers which can no longer * be accepted because they would violate * time_backtrack. */ void packet_id_reap (struct packet_id_rec *p) { const time_t local_now = now; if (p->time_backtrack) { int i; bool expire = false; for (i = 0; i < CIRC_LIST_SIZE (p->seq_list); ++i) { const time_t t = CIRC_LIST_ITEM (p->seq_list, i); if (t == SEQ_EXPIRED) break; if (!expire && t && t + p->time_backtrack < local_now) expire = true; if (expire) CIRC_LIST_ITEM (p->seq_list, i) = SEQ_EXPIRED; } } p->last_reap = local_now; } /* * Return true if packet id is ok, or false if * it is a replay. */ bool packet_id_test (const struct packet_id_rec *p, const struct packet_id_net *pin) { static int max_backtrack_stat; packet_id_type diff; dmsg (D_PID_DEBUG, "PID TEST " time_format ":" packet_id_format " " time_format ":" packet_id_format "", (time_type)p->time, (packet_id_print_type)p->id, (time_type)pin->time, (packet_id_print_type)pin->id); ASSERT (p->initialized); if (!pin->id) return false; if (p->seq_backtrack) { /* * In backtrack mode, we allow packet reordering subject * to the seq_backtrack and time_backtrack constraints. * * This mode is used with UDP. */ if (pin->time == p->time) { /* is packet-id greater than any one we've seen yet? */ if (pin->id > p->id) return true; /* check packet-id sliding window for original/replay status */ diff = p->id - pin->id; /* keep track of maximum backtrack seen for debugging purposes */ if ((int)diff > max_backtrack_stat) { max_backtrack_stat = (int)diff; msg (D_BACKTRACK, "Replay-window backtrack occurred [%d]", max_backtrack_stat); } if (diff >= (packet_id_type) CIRC_LIST_SIZE (p->seq_list)) return false; return CIRC_LIST_ITEM (p->seq_list, diff) == 0; } else if (pin->time < p->time) /* if time goes back, reject */ return false; else /* time moved forward */ return true; } else { /* * In non-backtrack mode, all sequence number series must * begin at some number n > 0 and must increment linearly without gaps. * * This mode is used with TCP. */ if (pin->time == p->time) return !p->id || pin->id == p->id + 1; else if (pin->time < p->time) /* if time goes back, reject */ return false; else /* time moved forward */ return pin->id == 1; } } /* * Read/write a packet ID to/from the buffer. Short form is sequence number * only. Long form is sequence number and timestamp. */ bool packet_id_read (struct packet_id_net *pin, struct buffer *buf, bool long_form) { packet_id_type net_id; net_time_t net_time; pin->id = 0; pin->time = 0; if (!buf_read (buf, &net_id, sizeof (net_id))) return false; pin->id = ntohpid (net_id); if (long_form) { if (!buf_read (buf, &net_time, sizeof (net_time))) return false; pin->time = ntohtime (net_time); } return true; } bool packet_id_write (const struct packet_id_net *pin, struct buffer *buf, bool long_form, bool prepend) { packet_id_type net_id = htonpid (pin->id); net_time_t net_time = htontime (pin->time); if (prepend) { if (long_form) { if (!buf_write_prepend (buf, &net_time, sizeof (net_time))) return false; } if (!buf_write_prepend (buf, &net_id, sizeof (net_id))) return false; } else { if (!buf_write (buf, &net_id, sizeof (net_id))) return false; if (long_form) { if (!buf_write (buf, &net_time, sizeof (net_time))) return false; } } return true; } const char * packet_id_net_print (const struct packet_id_net *pin, bool print_timestamp, struct gc_arena *gc) { struct buffer out = alloc_buf_gc (256, gc); buf_printf (&out, "[ #" packet_id_format, (packet_id_print_type)pin->id); if (print_timestamp && pin->time) buf_printf (&out, " / time = (" packet_id_format ") %s", (packet_id_print_type)pin->time, time_string (pin->time, 0, false, gc)); buf_printf (&out, " ]"); return BSTR (&out); } /* initialize the packet_id_persist structure in a disabled state */ void packet_id_persist_init (struct packet_id_persist *p) { p->filename = NULL; p->fd = -1; p->time = p->time_last_written = 0; p->id = p->id_last_written = 0; } /* close the file descriptor if it is open, and switch to disabled state */ void packet_id_persist_close (struct packet_id_persist *p) { if (packet_id_persist_enabled (p)) { if (close (p->fd)) msg (D_PID_PERSIST | M_ERRNO, "Close error on --replay-persist file %s", p->filename); packet_id_persist_init (p); } } /* load persisted rec packet_id (time and id) only once from file, and set state to enabled */ void packet_id_persist_load (struct packet_id_persist *p, const char *filename) { struct gc_arena gc = gc_new (); if (!packet_id_persist_enabled (p)) { /* open packet-id persist file for both read and write */ p->fd = open (filename, O_CREAT | O_RDWR | O_BINARY, S_IRUSR | S_IWUSR); if (p->fd == -1) { msg (D_PID_PERSIST | M_ERRNO, "Cannot open --replay-persist file %s for read/write", filename); } else { struct packet_id_persist_file_image image; ssize_t n; #if defined(HAVE_FLOCK) && defined(LOCK_EX) && defined(LOCK_NB) if (flock (p->fd, LOCK_EX | LOCK_NB)) msg (M_ERR, "Cannot obtain exclusive lock on --replay-persist file %s", filename); #endif p->filename = filename; n = read (p->fd, &image, sizeof(image)); if (n == sizeof(image)) { p->time = p->time_last_written = image.time; p->id = p->id_last_written = image.id; dmsg (D_PID_PERSIST_DEBUG, "PID Persist Read from %s: %s", p->filename, packet_id_persist_print (p, &gc)); } else if (n == -1) { msg (D_PID_PERSIST | M_ERRNO, "Read error on --replay-persist file %s", p->filename); } } } gc_free (&gc); } /* save persisted rec packet_id (time and id) to file (only if enabled state) */ void packet_id_persist_save (struct packet_id_persist *p) { if (packet_id_persist_enabled (p) && p->time && (p->time != p->time_last_written || p->id != p->id_last_written)) { struct packet_id_persist_file_image image; ssize_t n; off_t seek_ret; struct gc_arena gc = gc_new (); image.time = p->time; image.id = p->id; seek_ret = lseek(p->fd, (off_t)0, SEEK_SET); if (seek_ret == (off_t)0) { n = write(p->fd, &image, sizeof(image)); if (n == sizeof(image)) { p->time_last_written = p->time; p->id_last_written = p->id; dmsg (D_PID_PERSIST_DEBUG, "PID Persist Write to %s: %s", p->filename, packet_id_persist_print (p, &gc)); } else { msg (D_PID_PERSIST | M_ERRNO, "Cannot write to --replay-persist file %s", p->filename); } } else { msg (D_PID_PERSIST | M_ERRNO, "Cannot seek to beginning of --replay-persist file %s", p->filename); } gc_free (&gc); } } /* transfer packet_id_persist -> packet_id */ void packet_id_persist_load_obj (const struct packet_id_persist *p, struct packet_id *pid) { if (p && pid && packet_id_persist_enabled (p) && p->time) { pid->rec.time = p->time; pid->rec.id = p->id; } } const char * packet_id_persist_print (const struct packet_id_persist *p, struct gc_arena *gc) { struct buffer out = alloc_buf_gc (256, gc); buf_printf (&out, "["); if (packet_id_persist_enabled (p)) { buf_printf (&out, " #" packet_id_format, (packet_id_print_type)p->id); if (p->time) buf_printf (&out, " / time = (" packet_id_format ") %s", (packet_id_print_type)p->time, time_string (p->time, 0, false, gc)); } buf_printf (&out, " ]"); return (char *)out.data; } #ifdef PID_TEST void packet_id_interactive_test () { struct packet_id pid; struct packet_id_net pin; bool long_form; bool count = 0; bool test; const int seq_backtrack = 10; const int time_backtrack = 10; packet_id_init (&pid, seq_backtrack, time_backtrack); while (true) { char buf[80]; if (!fgets(buf, sizeof(buf), stdin)) break; update_time (); if (sscanf (buf, "%lu,%u", &pin.time, &pin.id) == 2) { packet_id_reap_test (&pid.rec); test = packet_id_test (&pid.rec, &pin); printf ("packet_id_test (" time_format ", " packet_id_format ") returned %d\n", (time_type)pin.time, (packet_id_print_type)pin.id, test); if (test) packet_id_add (&pid.rec, &pin); } else { long_form = (count < 20); packet_id_alloc_outgoing (&pid.send, &pin, long_form); printf ("(" time_format "(" packet_id_format "), %d)\n", (time_type)pin.time, (packet_id_print_type)pin.id, long_form); if (pid.send.id == 10) pid.send.id = 0xFFFFFFF8; ++count; } } packet_id_free (&pid); } #endif #endif /* USE_CRYPTO */