Mercurial > notdcc
view dccd/dccd_defs.h @ 6:c7785b85f2d2 default tip
Init scripts try to conform LSB header
author | Peter Gervai <grin@grin.hu> |
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date | Tue, 10 Mar 2009 15:15:36 +0100 |
parents | c7f6b056b673 |
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/* Distributed Checksum Clearinghouse * * server daemon definitions * * Copyright (c) 2008 by Rhyolite Software, LLC * * This agreement is not applicable to any entity which sells anti-spam * solutions to others or provides an anti-spam solution as part of a * security solution sold to other entities, or to a private network * which employs the DCC or uses data provided by operation of the DCC * but does not provide corresponding data to other users. * * Permission to use, copy, modify, and distribute this software without * changes for any purpose with or without fee is hereby granted, provided * that the above copyright notice and this permission notice appear in all * copies and any distributed versions or copies are either unchanged * or not called anything similar to "DCC" or "Distributed Checksum * Clearinghouse". * * Parties not eligible to receive a license under this agreement can * obtain a commercial license to use DCC by contacting Rhyolite Software * at sales@rhyolite.com. * * A commercial license would be for Distributed Checksum and Reputation * Clearinghouse software. That software includes additional features. This * free license for Distributed ChecksumClearinghouse Software does not in any * way grant permision to use Distributed Checksum and Reputation Clearinghouse * software * * THE SOFTWARE IS PROVIDED "AS IS" AND RHYOLITE SOFTWARE, LLC DISCLAIMS ALL * WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL RHYOLITE SOFTWARE, LLC * BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES * OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, * WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, * ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS * SOFTWARE. * * Rhyolite Software DCC 1.3.103-1.221 $Revision$ */ #ifndef DCCD_DEFS_H #define DCCD_DEFS_H #include "srvr_defs.h" #include "dcc_xhdr.h" extern DCC_EMSG dcc_emsg; extern u_char grey; extern u_char background; extern int stopint; extern DCC_SRVR_ID my_srvr_id; extern const char *brand; /* our brand name */ extern u_char use_ipv6; extern u_int16_t def_port; typedef struct srvr_soc { struct srvr_soc *fwd; DCC_SOCKU su; union { struct dcc_in6_addr in6; struct in_addr in4; } arg_addr; int udp; int listen; u_int16_t arg_port; u_char arg_family; u_char flags; # define SRVR_SOC_ADDR 0x01 /* explicit IP address */ # define SRVR_SOC_IF 0x02 /* port on all interfaces */ # define SRVR_SOC_LISTEN 0x04 /* need a listen socket for port */ # define SRVR_SOC_MARK 0X08 # define SRVR_SOC_NEW 0X10 } SRVR_SOC; extern SRVR_SOC *srvr_socs; extern int srvr_rcvbuf; #define MAX_CMD_CLOCK_SKEW (DCC_MAX_RETRANS_DELAY_SECS*2) #define MAX_FLOD_CLOCK_SKEW (4*60*60) /* refuse reports this far in advance */ extern char our_hostname[MAXHOSTNAMELEN]; extern DCC_SUM host_id_sum; /* advertised with our server-ID */ extern time_t host_id_next, host_id_last; #define DCC_SRVR_ID_SECS (24*60*60) /* defend server-IDs this often */ #define DCC_SRVR_ID_SECS_ST (5*60) /* defend after daemon starts */ extern int flod_trace_gen; /* unsuppress tracing */ /* keepalive intervals * An idle flooding link is kept alive, or known to be healthy, by the * receiving server repeating its current position. If the link is * broken, the receiving server's transmissions of its position will fail * and the transmitting server will hear silence on the link. */ #define KEEPALIVE_IN (10*60) #define KEEPALIVE_OUT (KEEPALIVE_IN+FLODS_CK_SECS) /* Things should be quicker while we are shutting down flooding * Some TCP/IP implementations have retransmission delays that can * totals 7 seconds, so we must not be too quick */ #define KEEPALIVE_IN_STOP 30 #define KEEPALIVE_OUT_STOP (KEEPALIVE_IN_STOP+FLODS_CK_SECS) /* be really quick if stopping the daemon */ #define SHUTDOWN_DELAY 2 #define IFP_DEAD(p,secs) DB_IS_TIME((p)->iflod_alive+(secs), secs) #define OFP_DEAD(p,secs) DB_IS_TIME((p)->oflod_alive+(secs), secs) /* Delay our reports and summaries of our reports by this much. * It should be long enough to allow us to generate useful summaries, but * it cannot be so long that we won't flood the summary when we make it. */ extern int summarize_delay_secs; extern int queue_max; extern u_char anon_off; /* turn off anonymous access */ extern u_char query_only; /* 1=treat reports as queries */ extern time_t anon_delay_us; /* anonymous client delay */ extern u_int anon_delay_inflate; extern struct timeval wake_time; /* when we awoke from select() */ extern struct timeval req_recv_time; /* when request arrived */ extern u_char grey_weak_body; /* 1=ignore bodies for greylisting */ extern u_char grey_weak_ip; /* 1=one good triple whitelists addr */ extern int grey_embargo; extern int grey_window; extern int grey_white; /* rate limiting * One of these structures is maintained for every recent client, * where "recent" is at least one day */ typedef u_int16_t RL_DATA_FG; # define RL_FG_MARKED 0x0001 /* seen during `cdcc clients` */ # define RL_FG_CK_BL 0x0002 /* 0=need to check list of addresses */ # define RL_FG_TRACE 0x0004 # define RL_FG_BL_ADDR 0x0008 /* blacklisted client or flood peer */ # define RL_FG_BL_ID 0x0010 /* blacklisted client ID */ # define RL_FG_BL_BAD 0x0020 /* ignored for bad behavior */ # define RL_FG_BLS (RL_FG_BL_ADDR | RL_FG_BL_ID | RL_FG_BL_BAD) # define RL_FG_PASSWD 0x0040 /* bad password */ # define RL_FG_UKN_ID 0x0080 /* bad ID */ # define RL_FG_ANON 0x0100 /* clnt_id=DCC_ID_ANON or bad */ typedef struct { u_int64_t requests; u_int64_t requests_old; u_int64_t nops; u_int64_t nops_old; time_t last_used; time_t requests_avg_start; /* effective start of averaging */ # define RL_AVG_TERM (60*60 * 48) time_t requests_avg_aged; /* when last updated */ # define RL_AVG_UPDATE (10*60) u_int requests_avg_total; u_int requests_avg; u_int nops_avg_total; u_int nops_avg; # define RL_REQUESTS_AVG(d) max((d)->requests_avg, (d)->requests) # define RL_NOPS_AVG(d) max((d)->nops_avg, (d)->nops) int request_credits; /* limit operations */ int bug_credits; /* limit complaints about this client */ DCC_CLNT_ID clnt_id; struct in6_addr clnt_addr; u_char pkt_vers; /* recent protocol version */ RL_DATA_FG flags; } RL_DATA; typedef struct rl { struct rl *hfwd, *hbak, **bin; /* neighbors in hash chain & the bin */ struct rl *older, *newer; /* global recently used chain */ RL_DATA d; short ref_cnt; /* in use by an entry in job queue */ } RL; /* rate-limit parameters * Decrease request_credits by RL_SCALE for each event. * Increase request_credits by .per_sec for every second. * When request_credits <= 0, there have been too many events. * Clamp request_credits at .lo to limit the duration of a penalty. * Clamp request_credits at .hi to limit the duration over which * the rate is averaged. */ typedef struct { float penalty_secs; /* drop excess events for this long */ int per_sec; /* allowed events/second * RL_SCALE */ int lo; /* clamp credit count at this */ int hi; /* reset credit count to this */ } RL_RATE; extern RL_RATE rl_sub_rate; /* X/sec/paying customer */ extern RL_RATE rl_anon_rate; /* X/sec/freeloader */ extern RL_RATE rl_all_anon_rate; /* X/sec for all freeloaders */ extern RL_RATE rl_bugs_rate; /* X complaints/sec */ #if defined(RL_MIN_MAX) #if RL_MIN_MAX<1000 || RL_MIN_MAX>1000000 #undef RL_MIN_MAX #endif #endif #define RL_MIN_MAX_DEF (10*1000) #define RL_MIN_MAX_MAX (1000*1000) /* fix ./configure if this changes */ #define RL_AVG_SECS 10 /* average for this many seconds */ #define RL_LIFE_SECS (RL_AVG_SECS*2) /* lifetime of rate limit block */ #define RL_OVF_CREDITS 0x7fffffff /* fit {bug,request}_credits */ #define RL_SCALE 10 #define RL_MAX_CREDITS (RL_OVF_CREDITS/RL_AVG_SECS/RL_SCALE/2) extern time_t clients_cleared; /* file containing rate limit blocks */ #define CLIENTS_NM() (grey_on ? "grey_clients" : "dccd_clients") #define BAD_CLIENTS_NM() (grey_on ? "grey_clients-bad" : "dccd_clients-bad") typedef struct { char magic[80]; char pad[40]; time_t now; time_t cleared; int32_t anon_delay_us; u_int32_t anon_delay_inflate; int hash_len; } CLIENTS_HEADER; #define CLIENTS_MAGIC_VERSION "7" #define CLIENTS_MAGIC_STR " client rate limit blocks version " #define CLIENTS_MAGIC_BASE(g) ((g) ? "greylist" CLIENTS_MAGIC_STR \ : "dccd" CLIENTS_MAGIC_STR) #define CLIENTS_MAGIC_V(g,v) ((g) ? "greylist" CLIENTS_MAGIC_STR v \ : "dccd" CLIENTS_MAGIC_STR v) #define CLIENTS_MAGIC(g) CLIENTS_MAGIC_V(g,CLIENTS_MAGIC_VERSION) /* report cache used to detect duplicate reports * One of these structures is maintained for every current operation */ typedef struct ridc { struct ridc *fwd, *bak, **hash; struct ridc *older, *newer; time_t last_used; DCC_HDR hdr; u_int16_t clnt_port; int len; u_char op; u_char bad; union { DCC_ANSWER_BODY_CKS b; DCC_ADMN_RESP_ANON_DELAY anon_delay; char msg[DCC_ERROR_MSG_LEN]; } result; } RIDC; /* entry in main job queue */ typedef struct dccd_queue { struct dccd_queue *later, *earlier; RL *rl; RIDC *ridc; SRVR_SOC *sp; DCC_CLNT_ID clnt_id; DCC_SOCKU clnt_su; /* send answer here */ u_int pkt_len; time_t delay_us; /* how long to delay the answer */ struct timeval answer; /* when it should be answered */ u_char flags; # define Q_FG_RPT_OK 0x01 /* override dccd -Q */ # define Q_FG_UNTRUSTED 0x02 # define Q_FG_UKN_ID 0x04 # define Q_FG_BAD_PASSWD 0x08 DCC_PASSWD passwd; /* sign answers with this */ union { DCC_HDR hdr; DCC_REPORT r; DCC_DELETE d; DCC_GREY_SPAM gs; DCC_ADMN_REQ ad; } pkt; } QUEUE; typedef struct iflod_info IFLOD_INFO; typedef struct { DCC_SRVR_ID from_lo; DCC_SRVR_ID from_hi; u_char result; } OFLOD_SRVR_ID_MAP; typedef enum { ID_MAP_NO, ID_MAP_REJ, ID_MAP_SELF } ID_MAP_RESULT; typedef struct { int cur, lim; /* signed because lim can be <0 */ } FLOD_LIMCNT; #define FLOD_LIM_CLEAR_SECS (5*60) #define FLOD_LIM_COMPLAINTS 10 typedef u_int OPT_FLAGS; typedef struct { OPT_FLAGS flags; # define FLOD_OPT_OFF 0x0001 # define FLOD_OPT_TRACE 0x0002 # define FLOD_OPT_TRACE2 0x0004 # define FLOD_OPT_ROGUE 0x0008 # define IFLOD_OPT_OFF_ROGUE(o) (((o)->i_opts.flags & FLOD_OPT_OFF) \ | ((o)->o_opts.flags&FLOD_OPT_ROGUE)) # define OFLOD_OPT_OFF_ROGUE(o) ((o)->o_opts.flags & (FLOD_OPT_OFF \ | FLOD_OPT_ROGUE)) # define FLOD_OPT_IPv4 0x0010 # define FLOD_OPT_IPv6 0x0020 # define FLOD_OPT_PASSIVE 0x0040 # define FLOD_OPT_SOCKS 0x0080 # define FLOD_OPT_NAT 0x0100 # define FLOD_OPT_DEL_OK 0x0200 # define FLOD_OPT_DEL_SET 0x0400 # define FLOD_OPT_NO_LOG_DEL 0x0800 # define FLOD_OPT_TRAPS 0x1000 # define FLOD_OPT_SIMPLE 0x2000 OFLOD_SRVR_ID_MAP srvr_map[10]; u_char num_maps; u_char path_len; } OFLOD_OPTS; typedef struct { FLOD_MMAP *mp; int soc; /* outgoing socket */ int lno; char rem_portname[sizeof(flod_mmaps->mmaps[0].rem_portname)]; char rem_hostname[sizeof(flod_mmaps->mmaps[0].rem_hostname)]; char loc_hostname[DCC_MAXDOMAINLEN]; DCC_SRVR_ID rem_id, in_passwd_id, out_passwd_id; u_int16_t rem_port, loc_port; DCC_SOCKU rem_su; /* target of the flood */ time_t limit_reset; /* when to reset complaint limits */ time_t oflod_alive; /* when last active */ struct { time_t saved; /* last wrote counts to file */ u_int out_reports; /* total reports sent */ u_int total; /* total reports received */ u_int accepted; /* acceptable received reports */ } cnts; struct { FLOD_LIMCNT stale; /* bad timestamp */ FLOD_LIMCNT dup; /* already received */ FLOD_LIMCNT wlist; /* whitelisted */ FLOD_LIMCNT not_deleted; /* delete commands ignored */ FLOD_LIMCNT bad_id; /* unrecognized server-IDs */ FLOD_LIMCNT complaint; /* output complaint from peer */ FLOD_LIMCNT iflod_bad; /* generic bad report */ } lc; DB_PTR xmit_pos; /* last transmitted position */ DB_PTR recv_pos; /* heard this from target */ DB_PTR cur_pos; /* completed to here */ DB_PTR rewind_pos; /* will have rewound by here */ int ibuf_len; union { DCC_FLOD_RESP r; u_char b[sizeof(DCC_FLOD_RESP)*2]; } ibuf; u_int obuf_len; union { DCC_FLOD_STREAM s; # define FLOD_BUF_SIZE 2048 u_char b[FLOD_BUF_SIZE]; } obuf; OFLOD_OPTS i_opts; OFLOD_OPTS o_opts; IFLOD_INFO *ifp; u_int flags; # define OFLOD_FG_CONNECTED 0x0001 /* connect() complete */ # define OFLOD_FG_NEW 0x0002 /* new connection */ # define OFLOD_FG_SHUTDOWN 0x0004 /* brakes applied */ # define OFLOD_FG_SHUTDOWN_REQ 0x0008 # define OFLOD_FG_HAVE_2PASSWD 0x0010 /* have a 2nd password */ # define OFLOD_FG_I_USED_2PASSWD 0x020 /* used the 2nd password */ # define OFLOD_FG_O_USED_2PASSWD 0x040 # define OFLOD_FG_EAGAIN 0x0080 /* recent bogus EAGAIN */ u_char oversion; } OFLOD_INFO; typedef struct { int total; /* known peers */ int open; /* active outgoing streams */ OFLOD_INFO infos[DCCD_MAX_FLOODS]; } OFLODS; extern OFLODS oflods; extern DB_PTR oflods_max_cur_pos; extern enum FLODS_ST { FLODS_ST_OFF, FLODS_ST_RESTART, FLODS_ST_ON } flods_st; extern DCC_TGTS flod_tholds[DCC_DIM_CKS]; struct iflod_info { int soc; /* incoming socket */ DCC_SOCKU rem_su; /* sender of the flood */ char rem_hostname[sizeof(flod_mmaps->mmaps[0].rem_hostname)]; DCC_FLOD_POS pos, pos_sent; OFLOD_INFO *ofp; time_t iflod_alive; /* when last active */ int ibuf_len; u_char flags; # define IFLOD_FG_CONNECTED 0x01 # define IFLOD_FG_CLIENT 0x02 /* outgoing connection */ # define IFLOD_FG_VERS_CK 0x04 # define IFLOD_FG_END_REQ 0x08 # define IFLOD_FG_FAST_LINGER 0x10 union { DCC_FLOD_STREAM s; u_char b[FLOD_BUF_SIZE]; } ibuf; }; typedef struct { int open; IFLOD_INFO infos[DCCD_MAX_FLOODS]; } IFLODS; extern IFLODS iflods; extern int flods_off; /* # of reasons flooding is off */ #define FLODS_OK() (!flods_off && !db_minimum_map) #define FLODS_OK_ON() (FLODS_OK() && flods_st == FLODS_ST_ON) extern u_int complained_many_iflods; typedef enum { WFIX_DELAY, /* waiting for window overflow */ WFIX_BUSY, /* measuring active load */ WFIX_QUIET, /* waiting for clients to flee */ WFIX_CHECK, /* counting clients that stayed */ } DBCLEAN_WFIX_STATE; extern DBCLEAN_WFIX_STATE dbclean_wfix_state; extern u_char stop_mode; /* 0=normal 1=reboot 2=with/DB clean */ extern time_t next_flods_ck; #define FLODS_CK_SECS 5 #define RUSH_NEXT_FLODS_CK() {if (next_flods_ck > db_time.tv_sec + 1) \ next_flods_ck = db_time.tv_sec + 1;} #define MISC_CK_SECS FLODS_CK_SECS #define CLIENTS_SAVE_SECS (30*60) extern time_t flod_mtime; #define FLOD_RETRY_SECS (5*60) /* retry connection no sooner */ #define FLOD_SUBMAX_RETRY_SECS (60*60) /* retry when peer can't poke us */ #define FLOD_MAX_RETRY_SECS (24*60*60) /* maximum backoff */ #define FLOD_SOCKS_SOCKS_IRETRY 30 #define FLOD_IN_COMPLAIN (24*60*60) /* complain daily about input */ #define FLOD_IN_COMPLAIN1 (2*60*60) /* 1st normal input complaint */ #define FLOD_IN_COMPLAIN_NOW (5*60) /* complain as soon as possible */ extern time_t iflods_ok_timer; /* incoming flooding ok since then */ #define IFLODS_OK_SECS (5*60) /* 5 minutes to catch up */ extern time_t need_clients_save; extern time_t got_hosts; /* resolve hostnames */ #define FLOD_NAMES_RESOLVE_SECS (5*60) /* at most every 5 minutes */ extern pid_t resolve_hosts_pid; extern const char *need_del_dbclean; extern time_t del_dbclean_next; #define DEL_DBCLEAN_SECS (30*60) /* limit dbclean if not urgent */ extern time_t dbclean_limit; #define DBCLEAN_LIMIT_SECS 15 /* not too often for any reason */ extern time_t dbclean_limit_secs; extern DCCD_STATS dccd_stats; /* Avoid the costs of generating and passing the args to syslog() by * checking bits in the caller. * If the server ran only on modern Unix, we could use gcc's macro varargs. */ #define TMSG_BIT(t) (DCC_TRACE_##t##_BIT & dccd_tracemask) #define TMSG_BLOCK(t,args) do {if TMSG_BIT(t) dcc_trace_msg args;} while (0) #define TMSG(t,p) TMSG_BLOCK(t,(p)) #define TMSG1(t,p,arg) TMSG_BLOCK(t,(p,arg)) #define TMSG2(t,p,arg1,arg2) TMSG_BLOCK(t,(p,arg1,arg2)) #define TMSG3(t,p,arg1,arg2,arg3) TMSG_BLOCK(t,(p,arg1,arg2,arg3)) #define TMSG4(t,p,arg1,arg2,arg3,arg4) TMSG_BLOCK(t,(p,arg1,arg2,arg3,arg4)) #define TMSG5(t,p,arg1,arg2,arg3,arg4,arg5) \ TMSG_BLOCK(t,(p,arg1,arg2,arg3,arg4,arg5)) #define TMSG_FB(ofp) ((DCC_TRACE_FLOD_BIT & dccd_tracemask) \ || ((ofp && (ofp->o_opts.flags & FLOD_OPT_TRACE)))) #define TMSG_Fsub(ofp,args) do {if (TMSG_FB(ofp)) dcc_trace_msg args;} while(0) #define TMSG_FLOD(ofp,p) TMSG_Fsub(ofp,(p)) #define TMSG1_FLOD(ofp,p,arg) TMSG_Fsub(ofp,(p,arg)) #define TMSG2_FLOD(ofp,p,arg1,arg2) TMSG_Fsub(ofp,(p,arg1,arg2)) #define TMSG3_FLOD(ofp,p,arg1,arg2,arg3) TMSG_Fsub(ofp,(p,arg1,arg2,arg3)) #define TMSG_FB2(ofp) (((DCC_TRACE_FLOD_BIT \ | DCC_TRACE_FLOD2_BIT) & dccd_tracemask) \ || ((ofp && (ofp->o_opts.flags \ & (FLOD_OPT_TRACE | FLOD_OPT_TRACE2))))) #define TMSG_F2sub(ofp,args) do {if (TMSG_FB2(ofp))dcc_trace_msg args;} while(0) #define TMSG_FLOD2(ofp,p) TMSG_F2sub(ofp,(p)) #define TMSG1_FLOD2(ofp,p,arg) TMSG_F2sub(ofp,(p,arg)) #define TMSG2_FLOD2(ofp,p,arg1,arg2) TMSG_F2sub(ofp,(p,arg1,arg2)) #define TMSG3_FLOD2(ofp,p,arg1,arg2,arg3) TMSG_F2sub(ofp,(p,arg1,arg2,arg3)) #define Q_CIP(q) dcc_su2str_err(&(q)->clnt_su) static inline void db_ptr2flod_pos(DCC_FLOD_POS bp, DB_PTR pos) { bp[7] = pos; bp[6] = pos>>8; bp[5] = pos>>16; bp[4] = pos>>24; bp[3] = pos>>32; bp[2] = pos>>40; bp[1] = pos>>48; bp[0] = pos>>56; } static inline DB_PTR flod_pos2db_ptr(const DCC_FLOD_POS pos) { return ((DB_PTR)pos[7] + (((DB_PTR)pos[6])<<8) + (((DB_PTR)pos[5])<<16) + (((DB_PTR)pos[4])<<24) + (((DB_PTR)pos[3])<<32) + (((DB_PTR)pos[2])<<40) + (((DB_PTR)pos[1])<<48) + (((DB_PTR)pos[0])<<56)); } /* multiplicative hash function after Knuth vol. 3 */ static inline u_int32_t mhash(u_int32_t hashin, u_int nbins) { u_int64_t v; v = 0x9ccf9319; v *= hashin; /* v=(hashin * Knuth's 0.6125423371 */ v &= 0xffffffff; /* fractional part or modulo 1 */ v *= nbins; return v >> 32; } /* dccd.c */ extern void free_q(QUEUE *); extern void after_fork(void); extern void set_dbclean_timer(void); extern void bad_stop(const char *, ...) PATTRIB(1,2); /* iflod.c */ extern ID_MAP_RESULT id_map(DCC_SRVR_ID, const OFLOD_OPTS *); extern const char * ifp_rem_str(const IFLOD_INFO *); #define CK_FLOD_CNTERR(lc) (++(lc)->cur <= ((lc)->lim + FLOD_LIM_COMPLAINTS)) extern void flod_cnterr(const FLOD_LIMCNT *, const char *, ...) PATTRIB(2,3); extern const char * ofp_rem_str(const OFLOD_INFO *); extern void rpt_err(OFLOD_INFO *, u_char, u_char, const char *, ...) PATTRIB(4,5); extern u_char set_flod_socket(OFLOD_INFO *, u_char, int, const char *, const DCC_SOCKU *); extern u_char flod_names_resolve_ck(void); extern u_char flod_names_resolve_start(void); extern void iflod_listen_close(SRVR_SOC *); extern void iflods_stop(const char *, u_char); extern void iflod_start(SRVR_SOC *); extern void iflods_listen(void); extern void iflod_socks_start(OFLOD_INFO *); extern u_char dccd_db_open(u_char); extern void iflod_close(IFLOD_INFO *, u_char, u_char, u_char, const char *, ...) PATTRIB(5,6); extern u_char iflod_read(IFLOD_INFO *); extern int iflod_send_pos(IFLOD_INFO *, u_char); extern int flods_list(char *, int, u_char); extern int flod_stats(char *, int, u_int32_t, u_char); /* oflod.c */ extern void oflods_clear(void); extern void oflod_open(OFLOD_INFO *); extern u_char load_flod(u_char); extern void save_flod_cnts(OFLOD_INFO *); extern void oflod_close(OFLOD_INFO *, u_char); extern int oflod_parse_eof(OFLOD_INFO *, u_char, const DCC_FLOD_END *, int); extern void oflod_read(OFLOD_INFO *); extern void oflod_write(OFLOD_INFO *); extern void flods_stop(const char *, u_char); extern const char *version_str(OFLOD_INFO *); extern void flod_try_again(OFLOD_INFO *); extern const char *flod_sign(OFLOD_INFO *, u_char, void *, int); extern u_char oflod_connect_fin(OFLOD_INFO *); extern void flods_restart(const char *, u_char); extern int check_load_ids(u_char); extern void flods_ck(u_char); extern void flods_init(void); /* rl.c */ extern void rl_inc(RL *, const RL_RATE *); extern void clients_save(void); extern void clients_load(void); extern u_char ck_ip_bl(RL **, DCC_CLNT_ID, const struct in6_addr *); extern void clients_get_id(DCC_ADMN_RESP_VAL *, int *, u_int, int, u_char, const struct in6_addr *, const struct in6_addr *); extern int clients_get(DCC_ADMN_RESP_VAL *, int *, u_int, int, u_char, const struct in6_addr *, const struct in6_addr *); #define CLIENTS_AGE (24*60*60) #define CLIENTS_SAVE_AGE (14*CLIENTS_AGE) extern void clients_clear(void); extern u_char ck_sign(const ID_TBL **, DCC_PASSWD, DCC_CLNT_ID, const void *, u_int); extern u_char ck_clnt_srvr_id(QUEUE *); extern u_char ck_clnt_id(QUEUE *); extern const char *qop2str(const QUEUE *); extern void check_blacklist_file(void); extern u_long dccd_tracemask; extern const char *from_id_ip(const QUEUE *, u_char); extern const char *op_id_ip(const QUEUE *); extern void vanon_msg(const char *, va_list); extern void anon_msg(const char *, ...) PATTRIB(1,2); extern void vclnt_msg(const QUEUE *, const char *, va_list); extern void clnt_msg(const QUEUE *, const char *, ...) PATTRIB(2,3); extern void drop_msg(QUEUE *, const char *, ...) PATTRIB(2,3); /* work.c */ extern int find_srvr_rcd(const DCC_SUM, const char *); extern int find_srvr_rcd_type(DCC_SRVR_ID); extern ID_TBL *find_srvr_type(DCC_SRVR_ID); extern void refresh_srvr_rcd(const DCC_SUM, DCC_SRVR_ID, const char *); extern void stats_clear(void); extern u_char summarize_dly(void); extern u_char add_dly_rcd(DB_RCD *, u_char); extern void do_work(QUEUE *); extern void do_grey(QUEUE *); extern void do_grey_spam(QUEUE *); extern void do_nop(QUEUE *); extern void do_admn(QUEUE *); extern void do_delete(QUEUE *); #endif /* DCCD_DEFS_H */