/* chronyd/chronyc - Programs for keeping computer clocks accurate. ********************************************************************** * Copyright (C) Richard P. Curnow 1997-2003 * Copyright (C) Miroslav Lichvar 2009-2011 * * 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. * ********************************************************************** ======================================================================= Module that reads and processes the configuration file. 1999-12-19 Kalle Olavi Niemitalo * conf.c: Added a new configuration setting "acquisitionport" and a function CNF_GetAcquisitionPort to read its value. (acquisition_port): New variable. (parse_port): Delegate most work to new function parse_some_port. (parse_acquisitionport): New function. (commands): Added "acquisitionport". (CNF_GetAcquisitionPort): New function. */ #include "sysincl.h" #include "conf.h" #include "ntp_sources.h" #include "ntp_core.h" #include "refclock.h" #include "cmdmon.h" #include "srcparams.h" #include "logging.h" #include "nameserv.h" #include "memory.h" #include "acquire.h" #include "cmdparse.h" #include "broadcast.h" #include "util.h" /* ================================================== */ #ifndef DEFAULT_CONF_DIR #define DEFAULT_CONF_DIR "/etc" #endif #define DEFAULT_CONF_FILE DEFAULT_CONF_DIR"/chrony.conf" /* ================================================== */ /* Forward prototypes */ static void parse_commandkey(const char *); static void parse_driftfile(const char *); static void parse_dumpdir(const char *); static void parse_dumponexit(const char *); static void parse_keyfile(const char *); static void parse_rtcfile(const char *); #if 1 // AVM static void parse_statfile(const char *); #endif static void parse_log(const char *); static void parse_logbanner(const char *); static void parse_logdir(const char *); static void parse_maxupdateskew(const char *); static void parse_maxclockerror(const char *); static void parse_reselectdist(const char *); static void parse_stratumweight(const char *); static void parse_peer(const char *); static void parse_acquisitionport(const char *); static void parse_port(const char *); static void parse_server(const char *); static void parse_refclock(const char *); static void parse_local(const char *); static void parse_manual(const char *); static void parse_initstepslew(const char *); static void parse_allow(const char *); static void parse_deny(const char *); static void parse_cmdallow(const char *); static void parse_cmddeny(const char *); static void parse_cmdport(const char *); static void parse_rtconutc(const char *); static void parse_rtcsync(const char *); static void parse_noclientlog(const char *); static void parse_clientloglimit(const char *); static void parse_fallbackdrift(const char *); static void parse_makestep(const char *); static void parse_logchange(const char *); static void parse_mailonchange(const char *); static void parse_bindaddress(const char *); static void parse_bindcmdaddress(const char *); static void parse_rtcdevice(const char *); static void parse_pidfile(const char *); static void parse_broadcast(const char *); static void parse_linux_hz(const char *); static void parse_linux_freq_scale(const char *); static void parse_sched_priority(const char *); static void parse_lockall(const char *); static void parse_tempcomp(const char *); /* ================================================== */ /* Configuration variables */ static char *rtc_device = "/dev/rtc"; static int acquisition_port = 0; /* 0 means let kernel choose port */ static int ntp_port = 123; static char *keys_file = NULL; static char *drift_file = NULL; static char *rtc_file = NULL; #if 1 // AVM static char *stat_file = NULL; #endif static unsigned long command_key_id; static double max_update_skew = 1000.0; static double max_clock_error = 10; /* in ppm */ static double reselect_distance = 1e-4; static double stratum_weight = 1.0; static int cmd_port = -1; static int do_log_measurements = 0; static int do_log_statistics = 0; static int do_log_tracking = 0; static int do_log_rtc = 0; static int do_log_refclocks = 0; static int do_log_tempcomp = 0; static int do_dump_on_exit = 0; static int log_banner = 32; static char *logdir = "."; static char *dumpdir = "."; static int enable_local=0; #define DEFAULT_LOCAL_STRATUM 8 static int local_stratum; static int do_init_stepslew = 0; static int n_init_srcs; /* Threshold (in seconds) - if absolute value of initial error is less than this, slew instead of stepping */ static int init_slew_threshold = -1; #define MAX_INIT_SRCS 8 static IPAddr init_srcs_ip[MAX_INIT_SRCS]; static int enable_manual=0; /* Flag set if the RTC runs UTC (default is it runs local time incl. daylight saving). */ static int rtc_on_utc = 0; /* Flag set if the RTC should be automatically synchronised by kernel */ static int rtc_sync = 0; /* Limit and threshold for clock stepping */ static int make_step_limit = 0; static double make_step_threshold = 0.0; /* Flag set if we should log to syslog when a time adjustment exceeding the threshold is initiated */ static int do_log_change = 0; static double log_change_threshold = 0.0; static char *mail_user_on_change = NULL; static double mail_change_threshold = 0.0; /* Flag indicating that we don't want to log clients, e.g. to save memory */ static int no_client_log = 0; /* Limit memory allocated for the clients log */ static unsigned long client_log_limit = 524288; /* Minimum and maximum fallback drift intervals */ static int fb_drift_min = 0; static int fb_drift_max = 0; /* IP addresses for binding the NTP socket to. UNSPEC family means INADDR_ANY will be used */ static IPAddr bind_address4, bind_address6; /* IP addresses for binding the command socket to. UNSPEC family means use the value of bind_address */ static IPAddr bind_cmd_address4, bind_cmd_address6; /* Filename to use for storing pid of running chronyd, to prevent multiple * chronyds being started. */ static char *pidfile = "/var/run/chronyd.pid"; /* Temperature sensor, update interval and compensation coefficients */ static char *tempcomp_file = NULL; static double tempcomp_interval; static double tempcomp_T0, tempcomp_k0, tempcomp_k1, tempcomp_k2; /* Boolean for whether the Linux HZ value has been overridden, and the * new value. */ static int set_linux_hz = 0; static int linux_hz; /* Boolean for whether the Linux frequency scaling value (i.e. the one that's * approx (1<= MAX_RCL_SOURCES) return; poll = 4; dpoll = 0; filter_length = 64; pps_rate = 0; offset = 0.0; delay = 1e-9; precision = 0.0; ref_id = 0; lock_ref_id = 0; sel_option = SRC_SelectNormal; if (sscanf(line, "%4s%n", name, &n) != 1) { LOG(LOGS_WARN, LOGF_Configure, "Could not read refclock driver name at line %d", line_number); return; } line += n; while (isspace(line[0])) line++; tmp = line; while (line[0] != '\0' && !isspace(line[0])) line++; if (line == tmp) { LOG(LOGS_WARN, LOGF_Configure, "Could not read refclock parameter at line %d", line_number); return; } param = MallocArray(char, 1 + line - tmp); strncpy(param, tmp, line - tmp); param[line - tmp] = '\0'; while (sscanf(line, "%10s%n", cmd, &n) == 1) { line += n; if (!strncasecmp(cmd, "refid", 5)) { if (sscanf(line, "%4s%n", (char *)ref, &n) != 1) break; ref_id = ref[0] << 24 | ref[1] << 16 | ref[2] << 8 | ref[3]; } else if (!strncasecmp(cmd, "lock", 4)) { if (sscanf(line, "%4s%n", (char *)ref, &n) != 1) break; lock_ref_id = ref[0] << 24 | ref[1] << 16 | ref[2] << 8 | ref[3]; } else if (!strncasecmp(cmd, "poll", 4)) { if (sscanf(line, "%d%n", &poll, &n) != 1) { break; } } else if (!strncasecmp(cmd, "dpoll", 5)) { if (sscanf(line, "%d%n", &dpoll, &n) != 1) { break; } } else if (!strncasecmp(cmd, "filter", 6)) { if (sscanf(line, "%d%n", &filter_length, &n) != 1) { break; } } else if (!strncasecmp(cmd, "rate", 4)) { if (sscanf(line, "%d%n", &pps_rate, &n) != 1) break; } else if (!strncasecmp(cmd, "offset", 6)) { if (sscanf(line, "%lf%n", &offset, &n) != 1) break; } else if (!strncasecmp(cmd, "delay", 5)) { if (sscanf(line, "%lf%n", &delay, &n) != 1) break; } else if (!strncasecmp(cmd, "precision", 9)) { if (sscanf(line, "%lf%n", &precision, &n) != 1) break; } else if (!strncasecmp(cmd, "noselect", 8)) { n = 0; sel_option = SRC_SelectNoselect; } else if (!strncasecmp(cmd, "prefer", 6)) { n = 0; sel_option = SRC_SelectPrefer; } else { LOG(LOGS_WARN, LOGF_Configure, "Unknown refclock parameter %s at line %d", cmd, line_number); break; } line += n; } strncpy(refclock_sources[i].driver_name, name, 4); refclock_sources[i].driver_parameter = param; refclock_sources[i].driver_poll = dpoll; refclock_sources[i].poll = poll; refclock_sources[i].filter_length = filter_length; refclock_sources[i].pps_rate = pps_rate; refclock_sources[i].offset = offset; refclock_sources[i].delay = delay; refclock_sources[i].precision = precision; refclock_sources[i].sel_option = sel_option; refclock_sources[i].ref_id = ref_id; refclock_sources[i].lock_ref_id = lock_ref_id; n_refclock_sources++; } /* ================================================== */ static void parse_some_port(const char *line, int *portvar) { if (sscanf(line, "%d", portvar) != 1) { LOG(LOGS_WARN, LOGF_Configure, "Could not read port number at line %d in file", line_number); } } /* ================================================== */ static void parse_acquisitionport(const char *line) { parse_some_port(line, &acquisition_port); } /* ================================================== */ static void parse_port(const char *line) { parse_some_port(line, &ntp_port); } /* ================================================== */ static void parse_maxupdateskew(const char *line) { if (sscanf(line, "%lf", &max_update_skew) != 1) { LOG(LOGS_WARN, LOGF_Configure, "Could not read max update skew at line %d in file", line_number); } } /* ================================================== */ static void parse_maxclockerror(const char *line) { if (sscanf(line, "%lf", &max_clock_error) != 1) { LOG(LOGS_WARN, LOGF_Configure, "Could not read max clock error at line %d in file", line_number); } } /* ================================================== */ static void parse_reselectdist(const char *line) { if (sscanf(line, "%lf", &reselect_distance) != 1) { LOG(LOGS_WARN, LOGF_Configure, "Could not read reselect distance at line %d in file", line_number); } } /* ================================================== */ static void parse_stratumweight(const char *line) { if (sscanf(line, "%lf", &stratum_weight) != 1) { LOG(LOGS_WARN, LOGF_Configure, "Could not read stratum weight at line %d in file", line_number); } } /* ================================================== */ static void parse_driftfile(const char *line) { /* This must allocate enough space! */ drift_file = MallocArray(char, 1 + strlen(line)); sscanf(line, "%s", drift_file); } /* ================================================== */ static void strip_trailing_spaces(char *p) { char *q; for (q=p; *q; q++) ; for (q--; isspace((unsigned char)*q); q--) ; *++q = 0; } /* ================================================== */ static void parse_keyfile(const char *line) { /* This must allocate enough space! */ keys_file = MallocArray(char, 1 + strlen(line)); sscanf(line, "%s", keys_file); strip_trailing_spaces(keys_file); } /* ================================================== */ #if 1 // AVM static void parse_statfile(const char *line) { stat_file = MallocArray(char, 1 + strlen(line)); sscanf(line, "%s", stat_file); strip_trailing_spaces(stat_file); } #endif /* ================================================== */ static void parse_rtcfile(const char *line) { rtc_file = MallocArray(char, 1 + strlen(line)); sscanf(line, "%s", rtc_file); strip_trailing_spaces(rtc_file); } /* ================================================== */ static void parse_rtcdevice(const char *line) { rtc_device = MallocArray(char, 1 + strlen(line)); sscanf(line, "%s", rtc_device); } /* ================================================== */ static void parse_logbanner(const char *line) { if (sscanf(line, "%d", &log_banner) != 1) { LOG(LOGS_WARN, LOGF_Configure, "Could not read logbanner number at line %d in file", line_number); } } /* ================================================== */ static void parse_logdir(const char *line) { logdir = MallocArray(char, 1 + strlen(line)); sscanf(line, "%s", logdir); } /* ================================================== */ static void parse_dumpdir(const char *line) { dumpdir = MallocArray(char, 1 + strlen(line)); sscanf(line, "%s", dumpdir); } /* ================================================== */ static void parse_dumponexit(const char *line) { do_dump_on_exit = 1; } /* ================================================== */ static void parse_log(const char *line) { do { while (*line && isspace((unsigned char)*line)) line++; if (*line) { if (!strncmp(line, "measurements", 12)) { do_log_measurements = 1; line += 12; } else if (!strncmp(line, "statistics", 10)) { do_log_statistics = 1; line += 10; } else if (!strncmp(line, "tracking", 8)) { do_log_tracking = 1; line += 8; } else if (!strncmp(line, "rtc", 3)) { do_log_rtc = 1; line += 3; } else if (!strncmp(line, "refclocks", 9)) { do_log_refclocks = 1; line += 9; } else if (!strncmp(line, "tempcomp", 8)) { do_log_tempcomp = 1; line += 8; } else { break; } } else { break; } } while (1); } /* ================================================== */ static void parse_commandkey(const char *line) { if (sscanf(line, "%lu", &command_key_id) != 1) { LOG(LOGS_WARN, LOGF_Configure, "Could not read command key ID at line %d", line_number); } } /* ================================================== */ static void parse_local(const char *line) { int stratum; enable_local = 1; if (sscanf(line, "%*[ \t]stratum%d", &stratum) == 1) { local_stratum = stratum; } else { local_stratum = DEFAULT_LOCAL_STRATUM; } } /* ================================================== */ static void parse_cmdport(const char *line) { if (sscanf(line, "%d", &cmd_port) != 1) { LOG(LOGS_WARN, LOGF_Configure, "Could not read command port number at line %d", line_number); } } /* ================================================== */ #define HOSTNAME_LEN 2047 #define SHOSTNAME_LEN "2047" static void parse_initstepslew(const char *line) { const char *p; char hostname[HOSTNAME_LEN+1]; int n; int threshold; IPAddr ip_addr; n_init_srcs = 0; p = line; if (sscanf(p, "%d%n", &threshold, &n) == 1) { p += n; } else { LOG(LOGS_WARN, LOGF_Configure, "Could not parse initstepslew threshold at line %d", line_number); return; } while (*p) { if (sscanf(p, "%" SHOSTNAME_LEN "s%n", hostname, &n) == 1) { if (DNS_Name2IPAddress(hostname, &ip_addr) == DNS_Success) { init_srcs_ip[n_init_srcs] = ip_addr; ++n_init_srcs; } if (n_init_srcs >= MAX_INIT_SRCS) { break; } } else { /* If we get invalid trailing syntax, forget it ... */ break; } p += n; } if (n_init_srcs > 0) { do_init_stepslew = 1; init_slew_threshold = threshold; } else { LOG(LOGS_WARN, LOGF_Configure, "No usable initstepslew servers at line %d\n", line_number); } } /* ================================================== */ static void parse_manual(const char *line) { enable_manual = 1; } /* ================================================== */ static void parse_rtconutc(const char *line) { rtc_on_utc = 1; } /* ================================================== */ static void parse_rtcsync(const char *line) { rtc_sync = 1; } /* ================================================== */ static void parse_noclientlog(const char *line) { no_client_log = 1; } /* ================================================== */ static void parse_clientloglimit(const char *line) { if (sscanf(line, "%lu", &client_log_limit) != 1) { LOG(LOGS_WARN, LOGF_Configure, "Could not read clientlog memory limit at line %d", line_number); } if (client_log_limit == 0) { /* unlimited */ client_log_limit = (unsigned long)-1; } } /* ================================================== */ static void parse_fallbackdrift(const char *line) { if (sscanf(line, "%d %d", &fb_drift_min, &fb_drift_max) != 2) { LOG(LOGS_WARN, LOGF_Configure, "Could not read fallback drift intervals at line %d", line_number); } } /* ================================================== */ static void parse_makestep(const char *line) { if (sscanf(line, "%lf %d", &make_step_threshold, &make_step_limit) != 2) { make_step_limit = 0; LOG(LOGS_WARN, LOGF_Configure, "Could not read threshold or update limit for stepping clock at line %d\n", line_number); } } /* ================================================== */ static void parse_logchange(const char *line) { if (sscanf(line, "%lf", &log_change_threshold) == 1) { do_log_change = 1; } else { do_log_change = 0; LOG(LOGS_WARN, LOGF_Configure, "Could not read threshold for logging clock changes at line %d\n", line_number); } } /* ================================================== */ #define BUFLEN 2047 #define SBUFLEN "2047" static void parse_mailonchange(const char *line) { char buffer[BUFLEN+1]; if (sscanf(line, "%" SBUFLEN "s%lf", buffer, &mail_change_threshold) == 2) { mail_user_on_change = MallocArray(char, strlen(buffer)+1); strcpy(mail_user_on_change, buffer); } else { mail_user_on_change = NULL; LOG(LOGS_WARN, LOGF_Configure, "Could not read user or threshold for clock change mail notify at line %d\n", line_number); } } /* ================================================== */ static void parse_allow_deny(const char *line, AllowDeny *list, int allow) { const char *p; unsigned long a, b, c, d, n; int all = 0; AllowDeny *new_node = NULL; IPAddr ip_addr; p = line; while (*p && isspace((unsigned char)*p)) p++; if (!strncmp(p, "all", 3)) { all = 1; p += 3; } while (*p && isspace((unsigned char)*p)) p++; if (!*p) { /* Empty line applies to all addresses */ new_node = MallocNew(AllowDeny); new_node->allow = allow; new_node->all = all; new_node->ip.family = IPADDR_UNSPEC; new_node->subnet_bits = 0; } else { char *slashpos; slashpos = strchr(p, '/'); if (slashpos) *slashpos = 0; n = 0; if (UTI_StringToIP(p, &ip_addr) || (n = sscanf(p, "%lu.%lu.%lu.%lu", &a, &b, &c, &d)) >= 1) { new_node = MallocNew(AllowDeny); new_node->allow = allow; new_node->all = all; if (n == 0) { new_node->ip = ip_addr; if (ip_addr.family == IPADDR_INET6) new_node->subnet_bits = 128; else new_node->subnet_bits = 32; } else { new_node->ip.family = IPADDR_INET4; a &= 0xff; b &= 0xff; c &= 0xff; d &= 0xff; switch (n) { case 1: new_node->ip.addr.in4 = (a<<24); new_node->subnet_bits = 8; break; case 2: new_node->ip.addr.in4 = (a<<24) | (b<<16); new_node->subnet_bits = 16; break; case 3: new_node->ip.addr.in4 = (a<<24) | (b<<16) | (c<<8); new_node->subnet_bits = 24; break; case 4: new_node->ip.addr.in4 = (a<<24) | (b<<16) | (c<<8) | d; new_node->subnet_bits = 32; break; default: assert(0); } } if (slashpos) { int specified_subnet_bits, n; n = sscanf(slashpos+1, "%d", &specified_subnet_bits); if (n == 1) { new_node->subnet_bits = specified_subnet_bits; } else { LOG(LOGS_WARN, LOGF_Configure, "Could not read subnet size at line %d", line_number); } } } else { if (DNS_Name2IPAddress(p, &ip_addr) == DNS_Success) { new_node = MallocNew(AllowDeny); new_node->allow = allow; new_node->all = all; new_node->ip = ip_addr; if (ip_addr.family == IPADDR_INET6) new_node->subnet_bits = 128; else new_node->subnet_bits = 32; } else { LOG(LOGS_WARN, LOGF_Configure, "Could not read address at line %d", line_number); } } } if (new_node) { new_node->prev = list->prev; new_node->next = list; list->prev->next = new_node; list->prev = new_node; } } /* ================================================== */ static void parse_allow(const char *line) { parse_allow_deny(line, &ntp_auth_list, 1); } /* ================================================== */ static void parse_deny(const char *line) { parse_allow_deny(line, &ntp_auth_list, 0); } /* ================================================== */ static void parse_cmdallow(const char *line) { parse_allow_deny(line, &cmd_auth_list, 1); } /* ================================================== */ static void parse_cmddeny(const char *line) { parse_allow_deny(line, &cmd_auth_list, 0); } /* ================================================== */ static void parse_bindaddress(const char *line) { IPAddr ip; char addr[51]; if (sscanf(line, "%50s", addr) == 1 && UTI_StringToIP(addr, &ip)) { if (ip.family == IPADDR_INET4) bind_address4 = ip; else if (ip.family == IPADDR_INET6) bind_address6 = ip; } else { LOG(LOGS_WARN, LOGF_Configure, "Could not read bind address at line %d\n", line_number); } } /* ================================================== */ static void parse_bindcmdaddress(const char *line) { IPAddr ip; char addr[51]; if (sscanf(line, "%50s", addr) == 1 && UTI_StringToIP(addr, &ip)) { if (ip.family == IPADDR_INET4) bind_cmd_address4 = ip; else if (ip.family == IPADDR_INET6) bind_cmd_address6 = ip; } else { LOG(LOGS_WARN, LOGF_Configure, "Could not read bind command address at line %d\n", line_number); } } /* ================================================== */ static void parse_pidfile(const char *line) { pidfile = MallocArray(char, 1 + strlen(line)); sscanf(line, "%s", pidfile); strip_trailing_spaces(pidfile); } /* ================================================== */ typedef struct { /* Both in host (not necessarily network) order */ IPAddr addr; unsigned short port; int interval; } NTP_Broadcast_Destination; static NTP_Broadcast_Destination *broadcasts = NULL; static int max_broadcasts = 0; static int n_broadcasts = 0; /* ================================================== */ static void parse_broadcast(const char *line) { /* Syntax : broadcast [] */ int port; int n; int interval; char addr[51]; IPAddr ip; n = sscanf(line, "%d %50s %d", &interval, addr, &port); if (n < 2 || !UTI_StringToIP(addr, &ip)) { LOG(LOGS_WARN, LOGF_Configure, "Could not parse broadcast directive at line %d", line_number); return; } else if (n == 2) { /* default port */ port = 123; } else if (n > 3) { LOG(LOGS_WARN, LOGF_Configure, "Too many fields in broadcast directive at line %d", line_number); } if (max_broadcasts == n_broadcasts) { /* Expand array */ max_broadcasts += 8; if (broadcasts) { broadcasts = ReallocArray(NTP_Broadcast_Destination, max_broadcasts, broadcasts); } else { broadcasts = MallocArray(NTP_Broadcast_Destination, max_broadcasts); } } broadcasts[n_broadcasts].addr = ip; broadcasts[n_broadcasts].port = port; broadcasts[n_broadcasts].interval = interval; ++n_broadcasts; } /* ================================================== */ static void parse_tempcomp(const char *line) { const char *tmp; while (isspace(line[0])) line++; tmp = line; while (line[0] != '\0' && !isspace(line[0])) line++; if (line == tmp) { LOG(LOGS_WARN, LOGF_Configure, "Could not read tempcomp filename at line %d", line_number); return; } if (sscanf(line, "%lf %lf %lf %lf %lf", &tempcomp_interval, &tempcomp_T0, &tempcomp_k0, &tempcomp_k1, &tempcomp_k2) != 5) { LOG(LOGS_WARN, LOGF_Configure, "Could not read tempcomp interval or coefficients at line %d", line_number); return; } tempcomp_file = MallocArray(char, 1 + line - tmp); strncpy(tempcomp_file, tmp, line - tmp); tempcomp_file[line - tmp] = '\0'; } /* ================================================== */ static void parse_linux_hz(const char *line) { if (1 == sscanf(line, "%d", &linux_hz)) { set_linux_hz = 1; } else { LOG(LOGS_WARN, LOGF_Configure, "Could not parse linux_hz directive at line %d", line_number); } } /* ================================================== */ static void parse_linux_freq_scale(const char *line) { if (1 == sscanf(line, "%lf", &linux_freq_scale)) { set_linux_freq_scale = 1; } else { LOG(LOGS_WARN, LOGF_Configure, "Could not parse linux_freq_scale directive at line %d", line_number); } } /* ================================================== */ void CNF_ProcessInitStepSlew(void (*after_hook)(void *), void *anything) { if (do_init_stepslew) { ACQ_StartAcquisition(n_init_srcs, init_srcs_ip, init_slew_threshold, after_hook, anything); } else { (after_hook)(anything); } } /* ================================================== */ void CNF_AddSources(void) { NTP_Remote_Address server; int i; for (i=0; inext) { status = NCR_AddAccessRestriction(&node->ip, node->subnet_bits, node->allow, node->all); if (!status) { LOG(LOGS_WARN, LOGF_Configure, "Bad subnet for %08lx", node->ip); } } for (node = cmd_auth_list.next; node != &cmd_auth_list; node = node->next) { status = CAM_AddAccessRestriction(&node->ip, node->subnet_bits, node->allow, node->all); if (!status) { LOG(LOGS_WARN, LOGF_Configure, "Bad subnet for %08lx", node->ip); } } return; } /* ================================================== */ int CNF_GetNoClientLog(void) { return no_client_log; } /* ================================================== */ unsigned long CNF_GetClientLogLimit(void) { return client_log_limit; } /* ================================================== */ void CNF_GetFallbackDrifts(int *min, int *max) { *min = fb_drift_min; *max = fb_drift_max; } /* ================================================== */ void CNF_GetBindAddress(int family, IPAddr *addr) { if (family == IPADDR_INET4) *addr = bind_address4; else if (family == IPADDR_INET6) *addr = bind_address6; else addr->family = IPADDR_UNSPEC; } /* ================================================== */ void CNF_GetBindCommandAddress(int family, IPAddr *addr) { if (family == IPADDR_INET4) *addr = bind_cmd_address4.family != IPADDR_UNSPEC ? bind_cmd_address4 : bind_address4; else if (family == IPADDR_INET6) *addr = bind_cmd_address6.family != IPADDR_UNSPEC ? bind_cmd_address6 : bind_address6; else addr->family = IPADDR_UNSPEC; } /* ================================================== */ char * CNF_GetPidFile(void) { return pidfile; } /* ================================================== */ void CNF_GetLinuxHz(int *set, int *hz) { *set = set_linux_hz; *hz = linux_hz; } /* ================================================== */ void CNF_GetLinuxFreqScale(int *set, double *freq_scale) { *set = set_linux_freq_scale; *freq_scale = linux_freq_scale ; } /* ================================================== */ int CNF_GetSchedPriority(void) { return sched_priority; } /* ================================================== */ int CNF_GetLockMemory(void) { return lock_memory; } /* ================================================== */ void CNF_GetTempComp(char **file, double *interval, double *T0, double *k0, double *k1, double *k2) { *file = tempcomp_file; *interval = tempcomp_interval; *T0 = tempcomp_T0; *k0 = tempcomp_k0; *k1 = tempcomp_k1; *k2 = tempcomp_k2; }