/* chronyd/chronyc - Programs for keeping computer clocks accurate. ********************************************************************** * Copyright (C) Miroslav Lichvar 2014-2016 * * 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. * ********************************************************************** ======================================================================= Function replacements needed when optional features are disabled. */ #include "config.h" #include "clientlog.h" #include "cmac.h" #include "cmdmon.h" #include "keys.h" #include "logging.h" #include "manual.h" #include "memory.h" #include "nameserv.h" #include "nameserv_async.h" #include "ntp_core.h" #include "ntp_io.h" #include "ntp_sources.h" #include "ntp_signd.h" #include "nts_ke_client.h" #include "nts_ke_server.h" #include "nts_ntp_client.h" #include "nts_ntp_server.h" #include "privops.h" #include "refclock.h" #include "sched.h" #include "util.h" #if defined(FEAT_NTP) && !defined(FEAT_ASYNCDNS) /* This is a blocking implementation used when asynchronous resolving is not available */ struct DNS_Async_Instance { const char *name; DNS_NameResolveHandler handler; void *arg; int pipe[2]; }; static void resolve_name(int fd, int event, void *anything) { struct DNS_Async_Instance *inst; IPAddr addrs[DNS_MAX_ADDRESSES]; DNS_Status status; int i; inst = (struct DNS_Async_Instance *)anything; SCH_RemoveFileHandler(inst->pipe[0]); close(inst->pipe[0]); close(inst->pipe[1]); status = PRV_Name2IPAddress(inst->name, addrs, DNS_MAX_ADDRESSES); for (i = 0; status == DNS_Success && i < DNS_MAX_ADDRESSES && addrs[i].family != IPADDR_UNSPEC; i++) ; (inst->handler)(status, i, addrs, inst->arg); Free(inst); } void DNS_Name2IPAddressAsync(const char *name, DNS_NameResolveHandler handler, void *anything) { struct DNS_Async_Instance *inst; inst = MallocNew(struct DNS_Async_Instance); inst->name = name; inst->handler = handler; inst->arg = anything; if (pipe(inst->pipe)) LOG_FATAL("pipe() failed"); UTI_FdSetCloexec(inst->pipe[0]); UTI_FdSetCloexec(inst->pipe[1]); SCH_AddFileHandler(inst->pipe[0], SCH_FILE_INPUT, resolve_name, inst); if (write(inst->pipe[1], "", 1) < 0) ; } #endif /* !FEAT_ASYNCDNS */ #ifndef FEAT_CMDMON void CAM_Initialise(void) { } void CAM_Finalise(void) { } void CAM_OpenUnixSocket(void) { } int CAM_AddAccessRestriction(IPAddr *ip_addr, int subnet_bits, int allow, int all) { return 1; } void MNL_Initialise(void) { } void MNL_Finalise(void) { } #endif /* !FEAT_CMDMON */ #ifndef FEAT_NTP void NCR_AddBroadcastDestination(NTP_Remote_Address *addr, int interval) { } void NCR_Initialise(void) { } void NCR_Finalise(void) { } int NCR_AddAccessRestriction(IPAddr *ip_addr, int subnet_bits, int allow, int all) { return 1; } int NCR_CheckAccessRestriction(IPAddr *ip_addr) { return 0; } void NIO_Initialise(void) { } void NIO_Finalise(void) { } void NSR_Initialise(void) { } void NSR_Finalise(void) { } NSR_Status NSR_AddSource(NTP_Remote_Address *remote_addr, NTP_Source_Type type, SourceParameters *params, uint32_t *conf_id) { return NSR_TooManySources; } NSR_Status NSR_AddSourceByName(char *name, int port, int pool, NTP_Source_Type type, SourceParameters *params, uint32_t *conf_id) { return NSR_TooManySources; } const char * NSR_StatusToString(NSR_Status status) { return "NTP not supported"; } NSR_Status NSR_RemoveSource(IPAddr *address) { return NSR_NoSuchSource; } void NSR_RemoveSourcesById(uint32_t conf_id) { } void NSR_RemoveAllSources(void) { } void NSR_HandleBadSource(IPAddr *address) { } void NSR_RefreshAddresses(void) { } char * NSR_GetName(IPAddr *address) { return NULL; } void NSR_SetSourceResolvingEndHandler(NSR_SourceResolvingEndHandler handler) { if (handler) (handler)(); } void NSR_ResolveSources(void) { } void NSR_StartSources(void) { } void NSR_AutoStartSources(void) { } int NSR_InitiateSampleBurst(int n_good_samples, int n_total_samples, IPAddr *mask, IPAddr *address) { return 0; } uint32_t NSR_GetLocalRefid(IPAddr *address) { return 0; } int NSR_SetConnectivity(IPAddr *mask, IPAddr *address, SRC_Connectivity connectivity) { return 0; } int NSR_ModifyMinpoll(IPAddr *address, int new_minpoll) { return 0; } int NSR_ModifyMaxpoll(IPAddr *address, int new_maxpoll) { return 0; } int NSR_ModifyMaxdelay(IPAddr *address, double new_max_delay) { return 0; } int NSR_ModifyMaxdelayratio(IPAddr *address, double new_max_delay_ratio) { return 0; } int NSR_ModifyMaxdelaydevratio(IPAddr *address, double new_max_delay_dev_ratio) { return 0; } int NSR_ModifyMinstratum(IPAddr *address, int new_min_stratum) { return 0; } int NSR_ModifyPolltarget(IPAddr *address, int new_poll_target) { return 0; } void NSR_ReportSource(RPT_SourceReport *report, struct timespec *now) { memset(report, 0, sizeof (*report)); } int NSR_GetAuthReport(IPAddr *address, RPT_AuthReport *report) { return 0; } int NSR_GetNTPReport(RPT_NTPReport *report) { return 0; } void NSR_GetActivityReport(RPT_ActivityReport *report) { memset(report, 0, sizeof (*report)); } void NSR_DumpAuthData(void) { } #ifndef FEAT_CMDMON void CLG_Initialise(void) { } void CLG_Finalise(void) { } void DNS_SetAddressFamily(int family) { } DNS_Status DNS_Name2IPAddress(const char *name, IPAddr *ip_addrs, int max_addrs) { return DNS_Failure; } void KEY_Initialise(void) { } void KEY_Finalise(void) { } #endif /* !FEAT_CMDMON */ #endif /* !FEAT_NTP */ #ifndef FEAT_REFCLOCK void RCL_Initialise(void) { } void RCL_Finalise(void) { } int RCL_AddRefclock(RefclockParameters *params) { return 0; } void RCL_StartRefclocks(void) { } void RCL_ReportSource(RPT_SourceReport *report, struct timespec *now) { memset(report, 0, sizeof (*report)); } #endif /* !FEAT_REFCLOCK */ #ifndef FEAT_SIGND void NSD_Initialise(void) { } void NSD_Finalise(void) { } int NSD_SignAndSendPacket(uint32_t key_id, NTP_Packet *packet, NTP_PacketInfo *info, NTP_Remote_Address *remote_addr, NTP_Local_Address *local_addr) { return 0; } #endif /* !FEAT_SIGND */ #ifndef HAVE_CMAC int CMC_GetKeyLength(CMC_Algorithm algorithm) { return 0; } CMC_Instance CMC_CreateInstance(CMC_Algorithm algorithm, const unsigned char *key, int length) { return NULL; } int CMC_Hash(CMC_Instance inst, const void *in, int in_len, unsigned char *out, int out_len) { return 0; } void CMC_DestroyInstance(CMC_Instance inst) { } #endif /* !HAVE_CMAC */ #ifndef FEAT_NTS void NNS_Initialise(void) { } void NNS_Finalise(void) { } int NNS_CheckRequestAuth(NTP_Packet *packet, NTP_PacketInfo *info, uint32_t *kod) { *kod = 0; return 0; } int NNS_GenerateResponseAuth(NTP_Packet *request, NTP_PacketInfo *req_info, NTP_Packet *response, NTP_PacketInfo *res_info, uint32_t kod) { return 0; } NNC_Instance NNC_CreateInstance(IPSockAddr *nts_address, const char *name, uint32_t cert_set, uint16_t ntp_port) { return NULL; } void NNC_DestroyInstance(NNC_Instance inst) { } int NNC_PrepareForAuth(NNC_Instance inst) { return 1; } int NNC_GenerateRequestAuth(NNC_Instance inst, NTP_Packet *packet, NTP_PacketInfo *info) { static int logged = 0; LOG(logged ? LOGS_DEBUG : LOGS_WARN, "Missing NTS support"); logged = 1; return 0; } int NNC_CheckResponseAuth(NNC_Instance inst, NTP_Packet *packet, NTP_PacketInfo *info) { return 0; } void NNC_ChangeAddress(NNC_Instance inst, IPAddr *address) { } void NNC_DumpData(NNC_Instance inst) { } void NNC_GetReport(NNC_Instance inst, RPT_AuthReport *report) { } void NKS_PreInitialise(uid_t uid, gid_t gid, int scfilter_level) { } void NKS_Initialise(void) { } void NKS_Finalise(void) { } void NKS_DumpKeys(void) { } void NKS_ReloadKeys(void) { } #endif /* !FEAT_NTS */