/* chronyd/chronyc - Programs for keeping computer clocks accurate. ********************************************************************** * Copyright (C) Richard P. Curnow 1997-2003 * Copyright (C) Miroslav Lichvar 2009-2015 * * This program is free software; you can redistribute it and/or modify * it under the terms of version 2 of the GNU General Public License 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; if not, write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. * ********************************************************************** ======================================================================= Core NTP protocol engine */ #include "config.h" #include "sysincl.h" #include "array.h" #include "ntp_core.h" #include "ntp_io.h" #include "memory.h" #include "sched.h" #include "reference.h" #include "local.h" #include "smooth.h" #include "sources.h" #include "util.h" #include "conf.h" #include "logging.h" #include "keys.h" #include "addrfilt.h" #include "clientlog.h" /* ================================================== */ static LOG_FileID logfileid; /* ================================================== */ /* Enumeration used for remembering the operating mode of one of the sources */ typedef enum { MD_OFFLINE, /* No sampling at all */ MD_ONLINE, /* Normal sampling based on sampling interval */ MD_BURST_WAS_OFFLINE, /* Burst sampling, return to offline afterwards */ MD_BURST_WAS_ONLINE, /* Burst sampling, return to online afterwards */ } OperatingMode; /* ================================================== */ /* Structure used for holding a single peer/server's protocol machine */ struct NCR_Instance_Record { NTP_Remote_Address remote_addr; /* Needed for routing transmit packets */ NTP_Local_Address local_addr; /* Local address/socket used to send packets */ NTP_Mode mode; /* The source's NTP mode (client/server or symmetric active peer) */ OperatingMode opmode; /* Whether we are sampling this source or not and in what way */ int timer_running; /* Boolean indicating whether we have a timeout pending to transmit to the source */ SCH_TimeoutID timeout_id; /* Scheduler's timeout ID, if we are running on a timer. */ int tx_suspended; /* Boolean indicating we can't transmit yet */ int auto_offline; /* If 1, automatically go offline if server/peer isn't responding */ int local_poll; /* Log2 of polling interval at our end */ int remote_poll; /* Log2 of server/peer's polling interval (recovered from received packets) */ int remote_stratum; /* Stratum of the server/peer (recovered from received packets) */ int presend_minpoll; /* If the current polling interval is at least this, an extra client packet will be send some time before normal transmit. This ensures that both us and the server/peer have an ARP entry for each other ready, which means our measurement is not botched by an ARP round-trip on one side or the other. */ int presend_done; /* The presend packet has been sent */ int minpoll; /* Log2 of minimum defined polling interval */ int maxpoll; /* Log2 of maximum defined polling interval */ int min_stratum; /* Increase stratum in received packets to the minimum */ int poll_target; /* Target number of sourcestats samples */ int version; /* Version set in packets for server/peer */ double poll_score; /* Score of current local poll */ double max_delay; /* Maximum round-trip delay to the peer that we can tolerate and still use the sample for generating statistics from */ double max_delay_ratio; /* Largest ratio of delay / min_delay_in_register that we can tolerate. */ double max_delay_dev_ratio; /* Maximum ratio of increase in delay / stddev */ int do_auth; /* Flag indicating whether we authenticate packets we send to this machine (if it's serving us or the association is symmetric). Note : we don't authenticate if we can't find the key in our database. */ uint32_t auth_key_id; /* The ID of the authentication key to use. */ /* Count of how many packets we have transmitted since last successful receive from this peer */ int tx_count; /* Timestamp in tx field of last received packet. We have to reproduce this exactly as the orig field or our outgoing packet. */ NTP_int64 remote_orig; /* Local timestamp when the last packet was received from the source. We have to be prepared to tinker with this if the local clock has its frequency adjusted before we repond. The value we store here is what our own local time was when the same arrived. Before replying, we have to correct this to fit with the parameters for the current reference. (It must be stored relative to local time to permit frequency and offset adjustments to be made when we trim the local clock). */ struct timeval local_rx; /* Local timestamp when we last transmitted a packet to the source. We store two versions. The first is in NTP format, and is used to validate the next received packet from the source. Additionally, this is corrected to bring it into line with the current reference. The second is in timeval format, and is kept relative to the local clock. We modify this in accordance with local clock frequency/offset changes, and use this for computing statistics about the source when a return packet arrives. */ NTP_int64 local_ntp_tx; struct timeval local_tx; /* The instance record in the main source management module. This performs the statistical analysis on the samples we generate */ SRC_Instance source; int burst_good_samples_to_go; int burst_total_samples_to_go; }; typedef struct { NTP_Remote_Address addr; NTP_Local_Address local_addr; int interval; } BroadcastDestination; /* Array of BroadcastDestination */ static ARR_Instance broadcasts; /* ================================================== */ /* Initial delay period before first packet is transmitted (in seconds) */ #define INITIAL_DELAY 0.2 /* Spacing required between samples for any two servers/peers (to minimise risk of network collisions) (in seconds) */ #define SAMPLING_SEPARATION 0.2 /* Randomness added to spacing between samples for one server/peer */ #define SAMPLING_RANDOMNESS 0.02 /* Adjustment of the peer polling interval */ #define PEER_SAMPLING_ADJ 1.1 /* Spacing between samples in burst mode for one server/peer */ #define BURST_INTERVAL 2.0 /* Time to wait before retransmitting in burst mode, if we did not get a reply to the previous probe */ #define BURST_TIMEOUT 2.0 /* Number of samples in initial burst */ #define IBURST_GOOD_SAMPLES 4 #define IBURST_TOTAL_SAMPLES SOURCE_REACH_BITS /* Time to wait after sending packet to 'warm up' link */ #define WARM_UP_DELAY 4.0 /* Compatible NTP protocol versions */ #define NTP_MAX_COMPAT_VERSION NTP_VERSION #define NTP_MIN_COMPAT_VERSION 1 /* Maximum allowed dispersion - as defined in RFC 5905 (16 seconds) */ #define NTP_MAX_DISPERSION 16.0 /* Invalid stratum number */ #define NTP_INVALID_STRATUM 0 /* Minimum and maximum allowed poll interval */ #define MIN_POLL 0 #define MAX_POLL 24 /* Kiss-o'-Death codes */ #define KOD_RATE 0x52415445UL /* RATE */ /* Maximum poll interval set by KoD RATE */ #define MAX_KOD_RATE_POLL SRC_DEFAULT_MAXPOLL /* Invalid socket, different from the one in ntp_io.c */ #define INVALID_SOCK_FD -2 /* ================================================== */ /* Server IPv4/IPv6 sockets */ static int server_sock_fd4; static int server_sock_fd6; static ADF_AuthTable access_auth_table; /* ================================================== */ /* Forward prototypes */ static void transmit_timeout(void *arg); static double get_transmit_delay(NCR_Instance inst, int on_tx, double last_tx); /* ================================================== */ static void do_size_checks(void) { /* Assertions to check the sizes of certain data types and the positions of certain record fields */ /* Check that certain invariants are true */ assert(sizeof(NTP_int32) == 4); assert(sizeof(NTP_int64) == 8); /* Check offsets of all fields in the NTP packet format */ assert(offsetof(NTP_Packet, lvm) == 0); assert(offsetof(NTP_Packet, stratum) == 1); assert(offsetof(NTP_Packet, poll) == 2); assert(offsetof(NTP_Packet, precision) == 3); assert(offsetof(NTP_Packet, root_delay) == 4); assert(offsetof(NTP_Packet, root_dispersion) == 8); assert(offsetof(NTP_Packet, reference_id) == 12); assert(offsetof(NTP_Packet, reference_ts) == 16); assert(offsetof(NTP_Packet, originate_ts) == 24); assert(offsetof(NTP_Packet, receive_ts) == 32); assert(offsetof(NTP_Packet, transmit_ts) == 40); } /* ================================================== */ static void do_time_checks(void) { struct timeval now; time_t warning_advance = 3600 * 24 * 365 * 10; /* 10 years */ #ifdef HAVE_LONG_TIME_T /* Check that time before NTP_ERA_SPLIT underflows correctly */ struct timeval tv1 = {NTP_ERA_SPLIT, 1}, tv2 = {NTP_ERA_SPLIT - 1, 1}; NTP_int64 ntv1, ntv2; int r; UTI_TimevalToInt64(&tv1, &ntv1, 0); UTI_TimevalToInt64(&tv2, &ntv2, 0); UTI_Int64ToTimeval(&ntv1, &tv1); UTI_Int64ToTimeval(&ntv2, &tv2); r = tv1.tv_sec == NTP_ERA_SPLIT && tv1.tv_sec + (1ULL << 32) - 1 == tv2.tv_sec; assert(r); LCL_ReadRawTime(&now); if (tv2.tv_sec - now.tv_sec < warning_advance) LOG(LOGS_WARN, LOGF_NtpCore, "Assumed NTP time ends at %s!", UTI_TimeToLogForm(tv2.tv_sec)); #else LCL_ReadRawTime(&now); if (now.tv_sec > 0x7fffffff - warning_advance) LOG(LOGS_WARN, LOGF_NtpCore, "System time ends at %s!", UTI_TimeToLogForm(0x7fffffff)); #endif } /* ================================================== */ void NCR_Initialise(void) { do_size_checks(); do_time_checks(); logfileid = CNF_GetLogMeasurements() ? LOG_FileOpen("measurements", " Date (UTC) Time IP Address L St 123 567 ABCD LP RP Score Offset Peer del. Peer disp. Root del. Root disp.") : -1; access_auth_table = ADF_CreateTable(); broadcasts = ARR_CreateInstance(sizeof (BroadcastDestination)); /* Server socket will be opened when access is allowed */ server_sock_fd4 = INVALID_SOCK_FD; server_sock_fd6 = INVALID_SOCK_FD; } /* ================================================== */ void NCR_Finalise(void) { unsigned int i; if (server_sock_fd4 != INVALID_SOCK_FD) NIO_CloseServerSocket(server_sock_fd4); if (server_sock_fd6 != INVALID_SOCK_FD) NIO_CloseServerSocket(server_sock_fd6); for (i = 0; i < ARR_GetSize(broadcasts); i++) NIO_CloseServerSocket(((BroadcastDestination *)ARR_GetElement(broadcasts, i))->local_addr.sock_fd); ARR_DestroyInstance(broadcasts); ADF_DestroyTable(access_auth_table); } /* ================================================== */ static void restart_timeout(NCR_Instance inst, double delay) { /* Check if we can transmit */ if (inst->tx_suspended) { assert(!inst->timer_running); return; } /* Stop old timer if running */ if (inst->timer_running) SCH_RemoveTimeout(inst->timeout_id); /* Start new timer for transmission */ inst->timeout_id = SCH_AddTimeoutInClass(delay, SAMPLING_SEPARATION, SAMPLING_RANDOMNESS, SCH_NtpSamplingClass, transmit_timeout, (void *)inst); inst->timer_running = 1; } /* ================================================== */ static void start_initial_timeout(NCR_Instance inst) { if (!inst->timer_running) { /* This will be the first transmission after mode change */ /* Mark source active */ SRC_SetActive(inst->source); } restart_timeout(inst, INITIAL_DELAY); } /* ================================================== */ static void close_client_socket(NCR_Instance inst) { if (inst->mode == MODE_CLIENT && inst->local_addr.sock_fd != INVALID_SOCK_FD) { NIO_CloseClientSocket(inst->local_addr.sock_fd); inst->local_addr.sock_fd = INVALID_SOCK_FD; } } /* ================================================== */ static void take_offline(NCR_Instance inst) { inst->opmode = MD_OFFLINE; if (inst->timer_running) { SCH_RemoveTimeout(inst->timeout_id); inst->timer_running = 0; } /* Mark source unreachable */ SRC_ResetReachability(inst->source); /* And inactive */ SRC_UnsetActive(inst->source); close_client_socket(inst); NCR_ResetInstance(inst); } /* ================================================== */ NCR_Instance NCR_GetInstance(NTP_Remote_Address *remote_addr, NTP_Source_Type type, SourceParameters *params) { NCR_Instance result; result = MallocNew(struct NCR_Instance_Record); result->remote_addr = *remote_addr; result->local_addr.ip_addr.family = IPADDR_UNSPEC; switch (type) { case NTP_SERVER: /* Client socket will be obtained when sending request */ result->local_addr.sock_fd = INVALID_SOCK_FD; result->mode = MODE_CLIENT; break; case NTP_PEER: result->local_addr.sock_fd = NIO_OpenServerSocket(remote_addr); result->mode = MODE_ACTIVE; break; default: assert(0); } result->minpoll = params->minpoll; if (result->minpoll < MIN_POLL) result->minpoll = SRC_DEFAULT_MINPOLL; else if (result->minpoll > MAX_POLL) result->minpoll = MAX_POLL; result->maxpoll = params->maxpoll; if (result->maxpoll < MIN_POLL) result->maxpoll = SRC_DEFAULT_MAXPOLL; else if (result->maxpoll > MAX_POLL) result->maxpoll = MAX_POLL; if (result->maxpoll < result->minpoll) result->maxpoll = result->minpoll; result->min_stratum = params->min_stratum; if (result->min_stratum >= NTP_MAX_STRATUM) result->min_stratum = NTP_MAX_STRATUM - 1; result->presend_minpoll = params->presend_minpoll; result->max_delay = params->max_delay; result->max_delay_ratio = params->max_delay_ratio; result->max_delay_dev_ratio = params->max_delay_dev_ratio; result->auto_offline = params->auto_offline; result->poll_target = params->poll_target; result->version = params->version; if (result->version < NTP_MIN_COMPAT_VERSION) result->version = NTP_MIN_COMPAT_VERSION; else if (result->version > NTP_VERSION) result->version = NTP_VERSION; if (params->authkey == INACTIVE_AUTHKEY) { result->do_auth = 0; result->auth_key_id = 0; } else { result->do_auth = 1; result->auth_key_id = params->authkey; if (!KEY_KeyKnown(result->auth_key_id)) { LOG(LOGS_WARN, LOGF_NtpCore, "Source %s added with unknown key %"PRIu32, UTI_IPToString(&result->remote_addr.ip_addr), result->auth_key_id); } } /* Create a source instance for this NTP source */ result->source = SRC_CreateNewInstance(UTI_IPToRefid(&remote_addr->ip_addr), SRC_NTP, params->sel_option, &result->remote_addr.ip_addr, params->min_samples, params->max_samples); result->timer_running = 0; result->timeout_id = 0; result->tx_suspended = 1; result->opmode = params->online ? MD_ONLINE : MD_OFFLINE; result->local_poll = result->minpoll; NCR_ResetInstance(result); if (params->iburst) { NCR_InitiateSampleBurst(result, IBURST_GOOD_SAMPLES, IBURST_TOTAL_SAMPLES); } return result; } /* ================================================== */ /* Destroy an instance */ void NCR_DestroyInstance(NCR_Instance instance) { if (instance->opmode != MD_OFFLINE) take_offline(instance); if (instance->mode == MODE_ACTIVE) NIO_CloseServerSocket(instance->local_addr.sock_fd); /* This will destroy the source instance inside the structure, which will cause reselection if this was the synchronising source etc. */ SRC_DestroyInstance(instance->source); /* Free the data structure */ Free(instance); } /* ================================================== */ void NCR_StartInstance(NCR_Instance instance) { instance->tx_suspended = 0; if (instance->opmode != MD_OFFLINE) start_initial_timeout(instance); } /* ================================================== */ void NCR_ResetInstance(NCR_Instance instance) { instance->tx_count = 0; instance->presend_done = 0; instance->poll_score = 0.0; instance->remote_poll = 0; instance->remote_stratum = 0; instance->remote_orig.hi = 0; instance->remote_orig.lo = 0; instance->local_rx.tv_sec = 0; instance->local_rx.tv_usec = 0; instance->local_tx.tv_sec = 0; instance->local_tx.tv_usec = 0; instance->local_ntp_tx.hi = 0; instance->local_ntp_tx.lo = 0; if (instance->local_poll != instance->minpoll) { instance->local_poll = instance->minpoll; /* The timer was set with a longer poll interval, restart it */ if (instance->timer_running) restart_timeout(instance, get_transmit_delay(instance, 0, 0.0)); } } /* ================================================== */ void NCR_ChangeRemoteAddress(NCR_Instance inst, NTP_Remote_Address *remote_addr) { inst->remote_addr = *remote_addr; inst->tx_count = 0; inst->presend_done = 0; if (inst->mode == MODE_CLIENT) close_client_socket(inst); else { NIO_CloseServerSocket(inst->local_addr.sock_fd); inst->local_addr.sock_fd = NIO_OpenServerSocket(remote_addr); } /* Update the reference ID and reset the source/sourcestats instances */ SRC_SetRefid(inst->source, UTI_IPToRefid(&remote_addr->ip_addr), &inst->remote_addr.ip_addr); SRC_ResetInstance(inst->source); } /* ================================================== */ static void adjust_poll(NCR_Instance inst, double adj) { inst->poll_score += adj; if (inst->poll_score >= 1.0) { inst->local_poll += (int)inst->poll_score; inst->poll_score -= (int)inst->poll_score; } if (inst->poll_score < 0.0) { inst->local_poll += (int)(inst->poll_score - 1.0); inst->poll_score -= (int)(inst->poll_score - 1.0); } /* Clamp polling interval to defined range */ if (inst->local_poll < inst->minpoll) { inst->local_poll = inst->minpoll; inst->poll_score = 0; } else if (inst->local_poll > inst->maxpoll) { inst->local_poll = inst->maxpoll; inst->poll_score = 1.0; } } /* ================================================== */ static double get_poll_adj(NCR_Instance inst, double error_in_estimate, double peer_distance) { double poll_adj; if (error_in_estimate > peer_distance) { int shift = 0; unsigned long temp = (int)(error_in_estimate / peer_distance); do { shift++; temp>>=1; } while (temp); poll_adj = -shift - inst->poll_score + 0.5; } else { int samples = SRC_Samples(inst->source); /* Adjust polling interval so that the number of sourcestats samples remains close to the target value */ poll_adj = ((double)samples / inst->poll_target - 1.0) / inst->poll_target; /* Make interval shortening quicker */ if (samples < inst->poll_target) { poll_adj *= 2.0; } } return poll_adj; } /* ================================================== */ static double get_transmit_delay(NCR_Instance inst, int on_tx, double last_tx) { int poll_to_use, stratum_diff; double delay_time; /* If we're in burst mode, queue for immediate dispatch. If we're operating in client/server mode, queue the timeout for the poll interval hence. The fact that a timeout has been queued in the transmit handler is immaterial - that is only done so that we at least send something, if no reply is heard. If we're in symmetric mode, we have to take account of the peer's wishes, otherwise his sampling regime will fall to pieces. If we're in client/server mode, we don't care what poll interval the server responded with last time. */ switch (inst->opmode) { case MD_OFFLINE: assert(0); break; case MD_ONLINE: /* Normal processing, depending on whether we're in client/server or symmetric mode */ switch(inst->mode) { case MODE_CLIENT: /* Client/server association - aim at some randomised time approx the poll interval away */ poll_to_use = inst->local_poll; delay_time = (double) (1UL<local_poll; if (poll_to_use > inst->remote_poll) poll_to_use = inst->remote_poll; if (poll_to_use < inst->minpoll) poll_to_use = inst->minpoll; delay_time = (double) (1UL<remote_stratum - REF_GetOurStratum(); if ((stratum_diff > 0 && last_tx * PEER_SAMPLING_ADJ < delay_time) || (!on_tx && !stratum_diff && last_tx / delay_time > PEER_SAMPLING_ADJ - 0.5)) delay_time *= PEER_SAMPLING_ADJ; /* Substract the already spend time */ if (last_tx > 0.0) delay_time -= last_tx; if (delay_time < 0.0) delay_time = 0.0; break; default: assert(0); break; } break; case MD_BURST_WAS_ONLINE: case MD_BURST_WAS_OFFLINE: /* Burst modes */ delay_time = on_tx ? BURST_TIMEOUT : BURST_INTERVAL; break; default: assert(0); break; } return delay_time; } /* ================================================== */ static int transmit_packet(NTP_Mode my_mode, /* The mode this machine wants to be */ int my_poll, /* The log2 of the local poll interval */ int version, /* The NTP version to be set in the packet */ int do_auth, /* Boolean indicating whether to authenticate the packet or not */ uint32_t key_id, /* The authentication key ID */ NTP_int64 *orig_ts, /* Originate timestamp (from received packet) */ struct timeval *local_rx, /* Local time request packet was received */ struct timeval *local_tx, /* RESULT : Time this reply is sent as local time, or NULL if don't want to know */ NTP_int64 *local_ntp_tx, /* RESULT : Time reply sent as NTP timestamp (including adjustment to reference), ignored if NULL */ NTP_Remote_Address *where_to, /* Where to address the reponse to */ NTP_Local_Address *from /* From what address to send it */ ) { NTP_Packet message; int leap, auth_len, length, ret; struct timeval local_receive, local_transmit; /* Parameters read from reference module */ int are_we_synchronised, our_stratum, smooth_time; NTP_Leap leap_status; uint32_t our_ref_id, ts_fuzz; struct timeval our_ref_time; double our_root_delay, our_root_dispersion, smooth_offset; /* Don't reply with version higher than ours */ if (version > NTP_VERSION) { version = NTP_VERSION; } /* This is accurate enough and cheaper than calling LCL_ReadCookedTime. A more accurate time stamp will be taken later in this function. */ SCH_GetLastEventTime(&local_transmit, NULL, NULL); REF_GetReferenceParams(&local_transmit, &are_we_synchronised, &leap_status, &our_stratum, &our_ref_id, &our_ref_time, &our_root_delay, &our_root_dispersion); /* Get current smoothing offset when sending packet to a client */ if (SMT_IsEnabled() && (my_mode == MODE_SERVER || my_mode == MODE_BROADCAST)) { smooth_offset = SMT_GetOffset(&local_transmit); smooth_time = fabs(smooth_offset) > LCL_GetSysPrecisionAsQuantum(); /* Suppress leap second when smoothing and slew mode are enabled */ if (REF_GetLeapMode() == REF_LeapModeSlew && (leap_status == LEAP_InsertSecond || leap_status == LEAP_DeleteSecond)) leap_status = LEAP_Normal; } else { smooth_time = 0; smooth_offset = 0.0; } if (smooth_time) { our_ref_id = NTP_REFID_SMOOTH; UTI_AddDoubleToTimeval(&our_ref_time, smooth_offset, &our_ref_time); UTI_AddDoubleToTimeval(local_rx, smooth_offset, &local_receive); } else { local_receive = *local_rx; } if (are_we_synchronised) { leap = (int) leap_status; } else { leap = LEAP_Unsynchronised; } /* Generate transmit packet */ message.lvm = NTP_LVM(leap, version, my_mode); /* Stratum 16 and larger are invalid */ if (our_stratum < NTP_MAX_STRATUM) { message.stratum = our_stratum; } else { message.stratum = NTP_INVALID_STRATUM; } message.poll = my_poll; message.precision = LCL_GetSysPrecisionAsLog(); /* If we're sending a client mode packet and we aren't synchronized yet, we might have to set up artificial values for some of these parameters */ message.root_delay = UTI_DoubleToInt32(our_root_delay); message.root_dispersion = UTI_DoubleToInt32(our_root_dispersion); message.reference_id = htonl(our_ref_id); /* Now fill in timestamps */ UTI_TimevalToInt64(&our_ref_time, &message.reference_ts, 0); /* Originate - this comes from the last packet the source sent us */ message.originate_ts = *orig_ts; /* Receive - this is when we received the last packet from the source. This timestamp will have been adjusted so that it will now look to the source like we have been running on our latest estimate of frequency all along */ UTI_TimevalToInt64(&local_receive, &message.receive_ts, 0); /* Prepare random bits which will be added to the transmit timestamp. */ ts_fuzz = UTI_GetNTPTsFuzz(message.precision); /* Transmit - this our local time right now! Also, we might need to store this for our own use later, next time we receive a message from the source we're sending to now. */ LCL_ReadCookedTime(&local_transmit, NULL); if (smooth_time) UTI_AddDoubleToTimeval(&local_transmit, smooth_offset, &local_transmit); length = NTP_NORMAL_PACKET_LENGTH; /* Authenticate */ if (do_auth && key_id) { /* Pre-compensate the transmit time by approx. how long it will take to generate the authentication data. */ local_transmit.tv_usec += KEY_GetAuthDelay(key_id); UTI_NormaliseTimeval(&local_transmit); UTI_TimevalToInt64(&local_transmit, &message.transmit_ts, ts_fuzz); auth_len = KEY_GenerateAuth(key_id, (unsigned char *) &message, offsetof(NTP_Packet, auth_keyid), (unsigned char *)&message.auth_data, sizeof (message.auth_data)); if (auth_len > 0) { message.auth_keyid = htonl(key_id); length += sizeof (message.auth_keyid) + auth_len; } else { DEBUG_LOG(LOGF_NtpCore, "Could not generate auth data with key %"PRIu32" to send packet", key_id); return 0; } } else { if (do_auth) { /* Zero key ID means crypto-NAK, append only the ID without any data */ message.auth_keyid = 0; length += sizeof (message.auth_keyid); } UTI_TimevalToInt64(&local_transmit, &message.transmit_ts, ts_fuzz); } ret = NIO_SendPacket(&message, where_to, from, length); if (local_tx) { *local_tx = local_transmit; } if (local_ntp_tx) { *local_ntp_tx = message.transmit_ts; } return ret; } /* ================================================== */ /* Timeout handler for transmitting to a source. */ static void transmit_timeout(void *arg) { NCR_Instance inst = (NCR_Instance) arg; int sent; inst->timer_running = 0; switch (inst->opmode) { case MD_BURST_WAS_ONLINE: /* With online burst switch to online before last packet */ if (inst->burst_total_samples_to_go <= 1) inst->opmode = MD_ONLINE; case MD_BURST_WAS_OFFLINE: if (inst->burst_total_samples_to_go <= 0) take_offline(inst); break; default: break; } /* With auto_offline take the source offline on 2nd missed reply */ if (inst->auto_offline && inst->tx_count >= 2) NCR_TakeSourceOffline(inst); if (inst->opmode == MD_OFFLINE) { return; } DEBUG_LOG(LOGF_NtpCore, "Transmit timeout for [%s:%d]", UTI_IPToString(&inst->remote_addr.ip_addr), inst->remote_addr.port); /* Open new client socket */ if (inst->mode == MODE_CLIENT) { close_client_socket(inst); assert(inst->local_addr.sock_fd == INVALID_SOCK_FD); inst->local_addr.sock_fd = NIO_OpenClientSocket(&inst->remote_addr); } /* Check whether we need to 'warm up' the link to the other end by sending an NTP exchange to ensure both ends' ARP caches are primed. On loaded systems this might also help ensure that bits of the program are paged in properly before we start. */ if ((inst->presend_minpoll > 0) && (inst->presend_minpoll <= inst->local_poll) && !inst->presend_done) { /* Send a client packet, don't store the local tx values as the reply will be ignored */ transmit_packet(MODE_CLIENT, inst->local_poll, inst->version, 0, 0, &inst->remote_orig, &inst->local_rx, NULL, NULL, &inst->remote_addr, &inst->local_addr); inst->presend_done = 1; /* Requeue timeout */ restart_timeout(inst, WARM_UP_DELAY); return; } inst->presend_done = 0; /* Reset for next time */ sent = transmit_packet(inst->mode, inst->local_poll, inst->version, inst->do_auth, inst->auth_key_id, &inst->remote_orig, &inst->local_rx, &inst->local_tx, &inst->local_ntp_tx, &inst->remote_addr, &inst->local_addr); ++inst->tx_count; /* If the source loses connectivity and our packets are still being sent, back off the sampling rate to reduce the network traffic. If it's the source to which we are currently locked, back off slowly. */ if (inst->tx_count >= 2) { /* Implies we have missed at least one transmission */ if (sent) { adjust_poll(inst, SRC_IsSyncPeer(inst->source) ? 0.1 : 0.25); } SRC_UpdateReachability(inst->source, 0); } switch (inst->opmode) { case MD_BURST_WAS_ONLINE: /* When not reachable, don't stop online burst until sending succeeds */ if (!sent && !SRC_IsReachable(inst->source)) break; /* Fall through */ case MD_BURST_WAS_OFFLINE: --inst->burst_total_samples_to_go; break; default: break; } /* Restart timer for this message */ restart_timeout(inst, get_transmit_delay(inst, 1, 0.0)); } /* ================================================== */ static int check_packet_format(NTP_Packet *message, int length) { int version; /* Check version and length */ version = NTP_LVM_TO_VERSION(message->lvm); if (version < NTP_MIN_COMPAT_VERSION || version > NTP_MAX_COMPAT_VERSION) { DEBUG_LOG(LOGF_NtpCore, "NTP packet has invalid version %d", version); return 0; } if (length < NTP_NORMAL_PACKET_LENGTH || (unsigned int)length % 4) { DEBUG_LOG(LOGF_NtpCore, "NTP packet has invalid length %d", length); return 0; } /* We can't reliably check the packet for invalid extension fields as we support MACs longer than the shortest valid extension field */ return 1; } /* ================================================== */ static int check_packet_auth(NTP_Packet *pkt, int length, int *has_auth, uint32_t *key_id) { int i, remainder, ext_length; unsigned char *data; uint32_t id; /* Go through extension fields and see if there is a valid MAC */ i = NTP_NORMAL_PACKET_LENGTH; data = (void *)pkt; while (1) { remainder = length - i; /* Check if the remaining data is a valid MAC. This needs to be done before trying to parse it as an extension field, because we support MACs longer than the shortest valid extension field. */ if (remainder >= NTP_MIN_MAC_LENGTH && remainder <= NTP_MAX_MAC_LENGTH) { id = ntohl(*(uint32_t *)(data + i)); if (KEY_CheckAuth(id, (void *)pkt, i, (void *)(data + i + 4), remainder - 4)) { if (key_id) *key_id = id; if (has_auth) *has_auth = 1; return 1; } } /* Check if this is a valid field extension. They consist of 16-bit type, 16-bit length of the whole field aligned to 32 bits and data. */ if (remainder >= NTP_MIN_EXTENSION_LENGTH) { ext_length = ntohs(*(uint16_t *)(data + i + 2)); if (ext_length >= NTP_MIN_EXTENSION_LENGTH && ext_length <= remainder && ext_length % 4 == 0) { i += ext_length; continue; } } /* Invalid or missing MAC, or format error */ break; } /* This is not 100% reliable as a MAC could fail to authenticate and could pass as an extension field, leaving reminder smaller than the minimum MAC length. Not a big problem, at worst we won't reply with a crypto-NAK. */ if (has_auth) *has_auth = remainder >= NTP_MIN_MAC_LENGTH; return 0; } /* ================================================== */ static int receive_packet(NTP_Packet *message, struct timeval *now, double now_err, NCR_Instance inst, NTP_Local_Address *local_addr, int length) { int pkt_leap; uint32_t pkt_refid, pkt_key_id; double pkt_root_delay; double pkt_root_dispersion; /* The local time to which the (offset, delay, dispersion) triple will be taken to relate. For client/server operation this is practically the same as either the transmit or receive time. The difference comes in symmetric active mode, when the receive may come minutes after the transmit, and this time will be midway between the two */ struct timeval sample_time; /* The estimated offset in seconds, a positive value indicates that the local clock is SLOW of the remote source and a negative value indicates that the local clock is FAST of the remote source */ double offset; /* The estimated peer delay, dispersion and distance */ double delay, dispersion, distance; /* The total root delay and dispersion */ double root_delay, root_dispersion; /* The skew and estimated frequency offset relative to the remote source */ double skew, source_freq_lo, source_freq_hi; /* These are the timeval equivalents of the remote epochs */ struct timeval remote_receive_tv, remote_transmit_tv; struct timeval remote_reference_tv; struct timeval local_average, remote_average; double local_interval, remote_interval; /* RFC 5905 packet tests */ int test1, test2, test3, test5, test6, test7; int valid_packet; /* Additional tests */ int testA, testB, testC, testD; int good_packet; /* Kiss-o'-Death codes */ int kod_rate; /* Characters used to print synchronisation status */ static const char sync_stats[4] = {'N', '+', '-', '?'}; /* The estimated offset predicted from previous samples. The convention here is that positive means local clock FAST of reference, i.e. backwards to the way that 'offset' is defined. */ double estimated_offset; /* The absolute difference between the offset estimate and measurement in seconds */ double error_in_estimate; double delay_time, precision; int requeue_transmit; /* ==================== */ pkt_leap = NTP_LVM_TO_LEAP(message->lvm); pkt_refid = ntohl(message->reference_id); pkt_root_delay = UTI_Int32ToDouble(message->root_delay); pkt_root_dispersion = UTI_Int32ToDouble(message->root_dispersion); UTI_Int64ToTimeval(&message->receive_ts, &remote_receive_tv); UTI_Int64ToTimeval(&message->transmit_ts, &remote_transmit_tv); UTI_Int64ToTimeval(&message->reference_ts, &remote_reference_tv); /* Check if the packet is valid per RFC 5905, section 8. The test values are 1 when passed and 0 when failed. */ /* Test 1 checks for duplicate packet */ test1 = message->transmit_ts.hi != inst->remote_orig.hi || message->transmit_ts.lo != inst->remote_orig.lo; /* Test 2 checks for bogus packet. This ensures the source is responding to the latest packet we sent to it. */ test2 = message->originate_ts.hi == inst->local_ntp_tx.hi && message->originate_ts.lo == inst->local_ntp_tx.lo; /* Test 3 checks for invalid timestamps. This can happen when the association if not properly 'up'. */ test3 = (message->originate_ts.hi || message->originate_ts.lo) && (message->receive_ts.hi || message->receive_ts.lo) && (message->reference_ts.hi || message->reference_ts.lo) && (message->transmit_ts.hi || message->transmit_ts.lo); /* Test 4 would check for denied access. It would always pass as this function is called only for known sources. */ /* Test 5 checks for authentication failure. If we expect authenticated info from this peer/server and the packet doesn't have it, the authentication is bad, or it's authenticated with a different key than expected, it's got to fail. If we don't expect the packet to be authenticated, just ignore the test. */ test5 = !inst->do_auth || (check_packet_auth(message, length, NULL, &pkt_key_id) && pkt_key_id == inst->auth_key_id); /* Test 6 checks for unsynchronised server */ test6 = pkt_leap != LEAP_Unsynchronised && message->stratum < NTP_MAX_STRATUM && message->stratum != NTP_INVALID_STRATUM; /* Test 7 checks for bad data. The root distance must be smaller than a defined maximum and the transmit time must not be before the time of the last synchronisation update. */ test7 = pkt_root_delay / 2.0 + pkt_root_dispersion < NTP_MAX_DISPERSION && UTI_CompareTimevals(&remote_reference_tv, &remote_transmit_tv) < 1; /* The packet is considered valid if the tests above passed */ valid_packet = test1 && test2 && test3 && test5 && test6 && test7; /* Check for Kiss-o'-Death codes */ kod_rate = 0; if (test1 && test2 && test5 && pkt_leap == LEAP_Unsynchronised && message->stratum == NTP_INVALID_STRATUM) { if (pkt_refid == KOD_RATE) kod_rate = 1; } /* The transmit timestamp and local receive timestamp must not be saved when the authentication test failed to prevent denial-of-service attacks on symmetric associations using authentication */ if (test5) { inst->remote_orig = message->transmit_ts; inst->local_rx = *now; } /* This protects against replay of the last packet we sent */ if (test2) inst->local_ntp_tx.hi = inst->local_ntp_tx.lo = 0; if (valid_packet) { precision = LCL_GetSysPrecisionAsQuantum() + UTI_Log2ToDouble(message->precision); SRC_GetFrequencyRange(inst->source, &source_freq_lo, &source_freq_hi); UTI_AverageDiffTimevals(&remote_receive_tv, &remote_transmit_tv, &remote_average, &remote_interval); UTI_AverageDiffTimevals(&inst->local_tx, now, &local_average, &local_interval); /* In our case, we work out 'delay' as the worst case delay, assuming worst case frequency error between us and the other source */ delay = local_interval - remote_interval * (1.0 + source_freq_lo); /* Clamp delay to avoid misleading results later */ delay = fabs(delay); if (delay < precision) delay = precision; /* Calculate offset. Following the NTP definition, this is negative if we are fast of the remote source. */ UTI_DiffTimevalsToDouble(&offset, &remote_average, &local_average); /* We treat the time of the sample as being midway through the local measurement period. An analysis assuming constant relative frequency and zero network delay shows this is the only possible choice to estimate the frequency difference correctly for every sample pair. */ sample_time = local_average; /* Calculate skew */ skew = (source_freq_hi - source_freq_lo) / 2.0; /* and then calculate peer dispersion */ dispersion = precision + now_err + skew * fabs(local_interval); /* Additional tests required to pass before accumulating the sample */ /* Test A requires that the round trip delay is less than an administrator-defined value */ testA = delay <= inst->max_delay; /* Test B requires that the ratio of the round trip delay to the minimum one currently in the stats data register is less than an administrator-defined value */ testB = inst->max_delay_ratio <= 1.0 || delay / SRC_MinRoundTripDelay(inst->source) <= inst->max_delay_ratio; /* Test C requires that the ratio of the increase in delay from the minimum one in the stats data register to the standard deviation of the offsets in the register is less than an administrator-defined value or the difference between measured offset and predicted offset is larger than the increase in delay */ testC = SRC_IsGoodSample(inst->source, -offset, delay, inst->max_delay_dev_ratio, LCL_GetMaxClockError(), &sample_time); /* Test D requires that the remote peer is not synchronised to us to prevent a synchronisation loop */ testD = message->stratum <= 1 || pkt_refid != UTI_IPToRefid(&local_addr->ip_addr); } else { offset = delay = dispersion = 0.0; sample_time = *now; testA = testB = testC = testD = 0; } /* The packet is considered good for synchronisation if the additional tests passed */ good_packet = testA && testB && testC && testD; root_delay = pkt_root_delay + delay; root_dispersion = pkt_root_dispersion + dispersion; distance = dispersion + 0.5 * delay; DEBUG_LOG(LOGF_NtpCore, "NTP packet lvm=%o stratum=%d poll=%d prec=%d root_delay=%f root_disp=%f refid=%"PRIx32" [%s]", message->lvm, message->stratum, message->poll, message->precision, pkt_root_delay, pkt_root_dispersion, pkt_refid, message->stratum == NTP_INVALID_STRATUM ? UTI_RefidToString(pkt_refid) : ""); DEBUG_LOG(LOGF_NtpCore, "reference=%s origin=%s receive=%s transmit=%s", UTI_TimestampToString(&message->reference_ts), UTI_TimestampToString(&message->originate_ts), UTI_TimestampToString(&message->receive_ts), UTI_TimestampToString(&message->transmit_ts)); DEBUG_LOG(LOGF_NtpCore, "offset=%f delay=%f dispersion=%f root_delay=%f root_dispersion=%f", offset, delay, dispersion, root_delay, root_dispersion); DEBUG_LOG(LOGF_NtpCore, "test123=%d%d%d test567=%d%d%d testABCD=%d%d%d%d kod_rate=%d valid=%d good=%d", test1, test2, test3, test5, test6, test7, testA, testB, testC, testD, kod_rate, valid_packet, good_packet); requeue_transmit = 0; /* Reduce polling rate if KoD RATE was received */ if (kod_rate) { if (message->poll > inst->minpoll) { /* Set our minpoll to message poll, but use a reasonable maximum */ if (message->poll <= MAX_KOD_RATE_POLL) inst->minpoll = message->poll; else if (inst->minpoll < MAX_KOD_RATE_POLL) inst->minpoll = MAX_KOD_RATE_POLL; if (inst->minpoll > inst->maxpoll) inst->maxpoll = inst->minpoll; if (inst->minpoll > inst->local_poll) inst->local_poll = inst->minpoll; LOG(LOGS_WARN, LOGF_NtpCore, "Received KoD RATE with poll %d from %s, minpoll set to %d", message->poll, UTI_IPToString(&inst->remote_addr.ip_addr), inst->minpoll); } /* Stop ongoing burst */ if (inst->opmode == MD_BURST_WAS_OFFLINE || inst->opmode == MD_BURST_WAS_ONLINE) { inst->burst_good_samples_to_go = 0; LOG(LOGS_WARN, LOGF_NtpCore, "Received KoD RATE from %s, burst sampling stopped", UTI_IPToString(&inst->remote_addr.ip_addr)); } requeue_transmit = 1; } if (valid_packet) { inst->remote_poll = message->poll; inst->remote_stratum = message->stratum; inst->tx_count = 0; SRC_UpdateReachability(inst->source, 1); if (good_packet) { /* Do this before we accumulate a new sample into the stats registers, obviously */ estimated_offset = SRC_PredictOffset(inst->source, &sample_time); SRC_AccumulateSample(inst->source, &sample_time, offset, delay, dispersion, root_delay, root_dispersion, message->stratum > inst->min_stratum ? message->stratum : inst->min_stratum, (NTP_Leap) pkt_leap); SRC_SelectSource(inst->source); /* Now examine the registers. First though, if the prediction is not even within +/- the peer distance of the peer, we are clearly not tracking the peer at all well, so we back off the sampling rate depending on just how bad the situation is. */ error_in_estimate = fabs(-offset - estimated_offset); /* Now update the polling interval */ adjust_poll(inst, get_poll_adj(inst, error_in_estimate, distance)); /* If we're in burst mode, check whether the burst is completed and revert to the previous mode */ switch (inst->opmode) { case MD_BURST_WAS_ONLINE: case MD_BURST_WAS_OFFLINE: --inst->burst_good_samples_to_go; if (inst->burst_good_samples_to_go <= 0) { if (inst->opmode == MD_BURST_WAS_ONLINE) inst->opmode = MD_ONLINE; else take_offline(inst); } break; default: break; } } else { /* Slowly increase the polling interval if we can't get good packet */ adjust_poll(inst, 0.1); } /* If in client mode, no more packets are expected to be coming from the server and the socket can be closed */ close_client_socket(inst); requeue_transmit = 1; } /* And now, requeue the timer. */ if (requeue_transmit && inst->opmode != MD_OFFLINE) { delay_time = get_transmit_delay(inst, 0, local_interval); if (kod_rate) { /* Back off for a while */ delay_time += (double) (4 * (1UL << inst->minpoll)); } /* Get rid of old timeout and start a new one */ assert(inst->timer_running); restart_timeout(inst, delay_time); } /* Do measurement logging */ if (logfileid != -1) { LOG_FileWrite(logfileid, "%s %-15s %1c %2d %1d%1d%1d %1d%1d%1d %1d%1d%1d%d %2d %2d %4.2f %10.3e %10.3e %10.3e %10.3e %10.3e", UTI_TimeToLogForm(sample_time.tv_sec), UTI_IPToString(&inst->remote_addr.ip_addr), sync_stats[pkt_leap], message->stratum, test1, test2, test3, test5, test6, test7, testA, testB, testC, testD, inst->local_poll, inst->remote_poll, inst->poll_score, offset, delay, dispersion, pkt_root_delay, pkt_root_dispersion); } return valid_packet; } /* ================================================== */ /* From RFC 5905, the standard handling of received packets, depending on the mode of the packet and of the source, is : +------------------+---------------------------------------+ | | Packet Mode | +------------------+-------+-------+-------+-------+-------+ | Association Mode | 1 | 2 | 3 | 4 | 5 | +------------------+-------+-------+-------+-------+-------+ | No Association 0 | NEWPS | DSCRD | FXMIT | MANY | NEWBC | | Symm. Active 1 | PROC | PROC | DSCRD | DSCRD | DSCRD | | Symm. Passive 2 | PROC | ERR | DSCRD | DSCRD | DSCRD | | Client 3 | DSCRD | DSCRD | DSCRD | PROC | DSCRD | | Server 4 | DSCRD | DSCRD | DSCRD | DSCRD | DSCRD | | Broadcast 5 | DSCRD | DSCRD | DSCRD | DSCRD | DSCRD | | Bcast Client 6 | DSCRD | DSCRD | DSCRD | DSCRD | PROC | +------------------+-------+-------+-------+-------+-------+ Association mode 0 is implemented in NCR_ProcessUnknown(), other modes in NCR_ProcessKnown(). Broadcast, manycast and ephemeral symmetric passive associations are not supported yet. */ /* ================================================== */ /* This routine is called when a new packet arrives off the network, and it relates to a source we have an ongoing protocol exchange with */ int NCR_ProcessKnown (NTP_Packet *message, /* the received message */ struct timeval *now, /* timestamp at time of receipt */ double now_err, NCR_Instance inst, /* the instance record for this peer/server */ NTP_Local_Address *local_addr, /* the receiving address */ int length /* the length of the received packet */ ) { int pkt_mode, proc_packet, proc_as_unknown, log_peer_access; if (!check_packet_format(message, length)) return 0; pkt_mode = NTP_LVM_TO_MODE(message->lvm); proc_packet = 0; proc_as_unknown = 0; log_peer_access = 0; /* Now, depending on the mode we decide what to do */ switch (pkt_mode) { case MODE_ACTIVE: switch (inst->mode) { case MODE_ACTIVE: /* Ordinary symmetric peering */ log_peer_access = 1; proc_packet = 1; break; case MODE_PASSIVE: /* In this software this case should not arise, we don't support unconfigured peers */ break; case MODE_CLIENT: /* This is where we have the remote configured as a server and he has us configured as a peer, process as from an unknown source */ proc_as_unknown = 1; break; default: /* Discard */ break; } break; case MODE_PASSIVE: switch (inst->mode) { case MODE_ACTIVE: /* This would arise if we have the remote configured as a peer and he does not have us configured */ log_peer_access = 1; proc_packet = 1; break; case MODE_PASSIVE: /* Error condition in RFC 5905 */ break; default: /* Discard */ break; } break; case MODE_CLIENT: /* If message is client mode, we just respond with a server mode packet, regardless of what we think the remote machine is supposed to be. However, even though this is a configured peer or server, we still implement access restrictions on client mode operation. This copes with the case for an isolated network where one machine is set by eye and is used as the master, with the other machines pointed at it. If the master goes down, we want to be able to reset its time at startup by relying on one of the secondaries to flywheel it. The behaviour coded here is required in the secondaries to make this possible. */ proc_as_unknown = 1; break; case MODE_SERVER: /* Ignore presend reply */ if (inst->presend_done) break; switch (inst->mode) { case MODE_CLIENT: /* Standard case where he's a server and we're the client */ proc_packet = 1; break; default: /* Discard */ break; } break; case MODE_BROADCAST: /* Just ignore these */ break; default: /* Obviously ignore */ break; } if (log_peer_access) CLG_LogNTPPeerAccess(&inst->remote_addr.ip_addr, now->tv_sec); if (proc_packet) { /* Check if the reply was received by the socket that sent the request */ if (local_addr->sock_fd != inst->local_addr.sock_fd) { DEBUG_LOG(LOGF_NtpCore, "Packet received by wrong socket %d (expected %d)", local_addr->sock_fd, inst->local_addr.sock_fd); return 0; } /* Ignore packets from offline sources */ if (inst->opmode == MD_OFFLINE || inst->tx_suspended) { DEBUG_LOG(LOGF_NtpCore, "Packet from offline source"); return 0; } return receive_packet(message, now, now_err, inst, local_addr, length); } else if (proc_as_unknown) { NCR_ProcessUnknown(message, now, now_err, &inst->remote_addr, local_addr, length); /* It's not a reply to our request, don't return success */ return 0; } else { DEBUG_LOG(LOGF_NtpCore, "NTP packet discarded pkt_mode=%d our_mode=%d", pkt_mode, inst->mode); return 0; } } /* ================================================== */ /* This routine is called when a new packet arrives off the network, and it relates to a source we don't know (not our server or peer) */ void NCR_ProcessUnknown (NTP_Packet *message, /* the received message */ struct timeval *now, /* timestamp at time of receipt */ double now_err, /* assumed error in the timestamp */ NTP_Remote_Address *remote_addr, NTP_Local_Address *local_addr, int length /* the length of the received packet */ ) { NTP_Mode pkt_mode, my_mode; int has_auth, valid_auth; uint32_t key_id; /* Ignore the packet if it wasn't received by server socket */ if (!NIO_IsServerSocket(local_addr->sock_fd)) { DEBUG_LOG(LOGF_NtpCore, "NTP request packet received by client socket %d", local_addr->sock_fd); return; } if (!check_packet_format(message, length)) return; if (!ADF_IsAllowed(access_auth_table, &remote_addr->ip_addr)) { DEBUG_LOG(LOGF_NtpCore, "NTP packet received from unauthorised host %s port %d", UTI_IPToString(&remote_addr->ip_addr), remote_addr->port); return; } pkt_mode = NTP_LVM_TO_MODE(message->lvm); switch (pkt_mode) { case MODE_ACTIVE: /* We are symmetric passive, even though we don't ever lock to him */ my_mode = MODE_PASSIVE; CLG_LogNTPPeerAccess(&remote_addr->ip_addr, now->tv_sec); break; case MODE_CLIENT: /* Reply with server packet */ my_mode = MODE_SERVER; CLG_LogNTPClientAccess(&remote_addr->ip_addr, now->tv_sec); break; default: /* Discard */ DEBUG_LOG(LOGF_NtpCore, "NTP packet discarded pkt_mode=%d", pkt_mode); return; } /* Check if the packet includes MAC that authenticates properly */ valid_auth = check_packet_auth(message, length, &has_auth, &key_id); /* If authentication failed, reply with crypto-NAK */ if (!valid_auth) key_id = 0; /* Send a reply. - copy the poll value as the client may use it to control its polling interval - authenticate the packet if the request was authenticated - originate timestamp is the client's transmit time - don't save our transmit timestamp as we aren't maintaining state about this client */ transmit_packet(my_mode, message->poll, NTP_LVM_TO_VERSION(message->lvm), has_auth, key_id, &message->transmit_ts, now, NULL, NULL, remote_addr, local_addr); } /* ================================================== */ void NCR_SlewTimes(NCR_Instance inst, struct timeval *when, double dfreq, double doffset) { double delta; if (inst->local_rx.tv_sec || inst->local_rx.tv_usec) UTI_AdjustTimeval(&inst->local_rx, when, &inst->local_rx, &delta, dfreq, doffset); if (inst->local_tx.tv_sec || inst->local_tx.tv_usec) UTI_AdjustTimeval(&inst->local_tx, when, &inst->local_tx, &delta, dfreq, doffset); } /* ================================================== */ void NCR_TakeSourceOnline(NCR_Instance inst) { switch (inst->opmode) { case MD_ONLINE: /* Nothing to do */ break; case MD_OFFLINE: LOG(LOGS_INFO, LOGF_NtpCore, "Source %s online", UTI_IPToString(&inst->remote_addr.ip_addr)); inst->opmode = MD_ONLINE; NCR_ResetInstance(inst); start_initial_timeout(inst); break; case MD_BURST_WAS_ONLINE: /* Will revert */ break; case MD_BURST_WAS_OFFLINE: inst->opmode = MD_BURST_WAS_ONLINE; LOG(LOGS_INFO, LOGF_NtpCore, "Source %s online", UTI_IPToString(&inst->remote_addr.ip_addr)); break; } } /* ================================================== */ void NCR_TakeSourceOffline(NCR_Instance inst) { switch (inst->opmode) { case MD_ONLINE: LOG(LOGS_INFO, LOGF_NtpCore, "Source %s offline", UTI_IPToString(&inst->remote_addr.ip_addr)); take_offline(inst); break; case MD_OFFLINE: break; case MD_BURST_WAS_ONLINE: inst->opmode = MD_BURST_WAS_OFFLINE; LOG(LOGS_INFO, LOGF_NtpCore, "Source %s offline", UTI_IPToString(&inst->remote_addr.ip_addr)); break; case MD_BURST_WAS_OFFLINE: break; } } /* ================================================== */ void NCR_ModifyMinpoll(NCR_Instance inst, int new_minpoll) { if (new_minpoll < MIN_POLL || new_minpoll > MAX_POLL) return; inst->minpoll = new_minpoll; LOG(LOGS_INFO, LOGF_NtpCore, "Source %s new minpoll %d", UTI_IPToString(&inst->remote_addr.ip_addr), new_minpoll); if (inst->maxpoll < inst->minpoll) NCR_ModifyMaxpoll(inst, inst->minpoll); } /* ================================================== */ void NCR_ModifyMaxpoll(NCR_Instance inst, int new_maxpoll) { if (new_maxpoll < MIN_POLL || new_maxpoll > MAX_POLL) return; inst->maxpoll = new_maxpoll; LOG(LOGS_INFO, LOGF_NtpCore, "Source %s new maxpoll %d", UTI_IPToString(&inst->remote_addr.ip_addr), new_maxpoll); if (inst->minpoll > inst->maxpoll) NCR_ModifyMinpoll(inst, inst->maxpoll); } /* ================================================== */ void NCR_ModifyMaxdelay(NCR_Instance inst, double new_max_delay) { inst->max_delay = new_max_delay; LOG(LOGS_INFO, LOGF_NtpCore, "Source %s new max delay %f", UTI_IPToString(&inst->remote_addr.ip_addr), new_max_delay); } /* ================================================== */ void NCR_ModifyMaxdelayratio(NCR_Instance inst, double new_max_delay_ratio) { inst->max_delay_ratio = new_max_delay_ratio; LOG(LOGS_INFO, LOGF_NtpCore, "Source %s new max delay ratio %f", UTI_IPToString(&inst->remote_addr.ip_addr), new_max_delay_ratio); } /* ================================================== */ void NCR_ModifyMaxdelaydevratio(NCR_Instance inst, double new_max_delay_dev_ratio) { inst->max_delay_dev_ratio = new_max_delay_dev_ratio; LOG(LOGS_INFO, LOGF_NtpCore, "Source %s new max delay dev ratio %f", UTI_IPToString(&inst->remote_addr.ip_addr), new_max_delay_dev_ratio); } /* ================================================== */ void NCR_ModifyMinstratum(NCR_Instance inst, int new_min_stratum) { inst->min_stratum = new_min_stratum; LOG(LOGS_INFO, LOGF_NtpCore, "Source %s new minstratum %d", UTI_IPToString(&inst->remote_addr.ip_addr), new_min_stratum); } /* ================================================== */ void NCR_ModifyPolltarget(NCR_Instance inst, int new_poll_target) { inst->poll_target = new_poll_target; LOG(LOGS_INFO, LOGF_NtpCore, "Source %s new polltarget %d", UTI_IPToString(&inst->remote_addr.ip_addr), new_poll_target); } /* ================================================== */ void NCR_InitiateSampleBurst(NCR_Instance inst, int n_good_samples, int n_total_samples) { if (inst->mode == MODE_CLIENT) { /* We want to prevent burst mode being used on symmetric active associations - it will play havoc with the peer's sampling strategy. (This obviously relies on us having the peer configured that way if he has us configured symmetric active - but there's not much else we can do.) */ switch (inst->opmode) { case MD_BURST_WAS_OFFLINE: case MD_BURST_WAS_ONLINE: /* If already burst sampling, don't start again */ break; case MD_ONLINE: case MD_OFFLINE: inst->opmode = inst->opmode == MD_ONLINE ? MD_BURST_WAS_ONLINE : MD_BURST_WAS_OFFLINE; inst->burst_good_samples_to_go = n_good_samples; inst->burst_total_samples_to_go = n_total_samples; start_initial_timeout(inst); break; default: assert(0); break; } } } /* ================================================== */ void NCR_ReportSource(NCR_Instance inst, RPT_SourceReport *report, struct timeval *now) { report->poll = inst->local_poll; switch (inst->mode) { case MODE_CLIENT: report->mode = RPT_NTP_CLIENT; break; case MODE_ACTIVE: report->mode = RPT_NTP_PEER; break; default: assert(0); } } /* ================================================== */ int NCR_AddAccessRestriction(IPAddr *ip_addr, int subnet_bits, int allow, int all) { ADF_Status status; if (allow) { if (all) { status = ADF_AllowAll(access_auth_table, ip_addr, subnet_bits); } else { status = ADF_Allow(access_auth_table, ip_addr, subnet_bits); } } else { if (all) { status = ADF_DenyAll(access_auth_table, ip_addr, subnet_bits); } else { status = ADF_Deny(access_auth_table, ip_addr, subnet_bits); } } if (status != ADF_SUCCESS) return 0; /* Keep server sockets open only when an address allowed */ if (allow) { NTP_Remote_Address remote_addr; if (server_sock_fd4 == INVALID_SOCK_FD && ADF_IsAnyAllowed(access_auth_table, IPADDR_INET4)) { remote_addr.ip_addr.family = IPADDR_INET4; server_sock_fd4 = NIO_OpenServerSocket(&remote_addr); } if (server_sock_fd6 == INVALID_SOCK_FD && ADF_IsAnyAllowed(access_auth_table, IPADDR_INET6)) { remote_addr.ip_addr.family = IPADDR_INET6; server_sock_fd6 = NIO_OpenServerSocket(&remote_addr); } } else { if (server_sock_fd4 != INVALID_SOCK_FD && !ADF_IsAnyAllowed(access_auth_table, IPADDR_INET4)) { NIO_CloseServerSocket(server_sock_fd4); server_sock_fd4 = INVALID_SOCK_FD; } if (server_sock_fd6 != INVALID_SOCK_FD && !ADF_IsAnyAllowed(access_auth_table, IPADDR_INET6)) { NIO_CloseServerSocket(server_sock_fd6); server_sock_fd6 = INVALID_SOCK_FD; } } return 1; } /* ================================================== */ int NCR_CheckAccessRestriction(IPAddr *ip_addr) { return ADF_IsAllowed(access_auth_table, ip_addr); } /* ================================================== */ void NCR_IncrementActivityCounters(NCR_Instance inst, int *online, int *offline, int *burst_online, int *burst_offline) { switch (inst->opmode) { case MD_BURST_WAS_OFFLINE: ++*burst_offline; break; case MD_BURST_WAS_ONLINE: ++*burst_online; break; case MD_ONLINE: ++*online; break; case MD_OFFLINE: ++*offline; break; default: assert(0); break; } } /* ================================================== */ NTP_Remote_Address * NCR_GetRemoteAddress(NCR_Instance inst) { return &inst->remote_addr; } /* ================================================== */ int NCR_IsSyncPeer(NCR_Instance inst) { return SRC_IsSyncPeer(inst->source); } /* ================================================== */ static void broadcast_timeout(void *arg) { BroadcastDestination *destination; NTP_int64 orig_ts; struct timeval recv_ts; destination = ARR_GetElement(broadcasts, (long)arg); orig_ts.hi = 0; orig_ts.lo = 0; recv_ts.tv_sec = 0; recv_ts.tv_usec = 0; transmit_packet(MODE_BROADCAST, 6 /* FIXME: should this be log2(interval)? */, NTP_VERSION, 0, 0, &orig_ts, &recv_ts, NULL, NULL, &destination->addr, &destination->local_addr); /* Requeue timeout. We don't care if interval drifts gradually. */ SCH_AddTimeoutInClass(destination->interval, SAMPLING_SEPARATION, SAMPLING_RANDOMNESS, SCH_NtpBroadcastClass, broadcast_timeout, arg); } /* ================================================== */ void NCR_AddBroadcastDestination(IPAddr *addr, unsigned short port, int interval) { BroadcastDestination *destination; destination = (BroadcastDestination *)ARR_GetNewElement(broadcasts); destination->addr.ip_addr = *addr; destination->addr.port = port; destination->local_addr.ip_addr.family = IPADDR_UNSPEC; destination->local_addr.sock_fd = NIO_OpenServerSocket(&destination->addr); destination->interval = interval; SCH_AddTimeoutInClass(destination->interval, SAMPLING_SEPARATION, SAMPLING_RANDOMNESS, SCH_NtpBroadcastClass, broadcast_timeout, (void *)(long)(ARR_GetSize(broadcasts) - 1)); }