/* Unix SMB/CIFS implementation. Samba internal messaging functions Copyright (C) Andrew Tridgell 2000 Copyright (C) 2001 by Martin Pool Copyright (C) 2002 by Jeremy Allison This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. 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., 675 Mass Ave, Cambridge, MA 02139, USA. */ /** @defgroup messages Internal messaging framework @{ @file messages.c @brief Module for internal messaging between Samba daemons. The idea is that if a part of Samba wants to do communication with another Samba process then it will do a message_register() of a dispatch function, and use message_send_pid() to send messages to that process. The dispatch function is given the pid of the sender, and it can use that to reply by message_send_pid(). See ping_message() for a simple example. @caution Dispatch functions must be able to cope with incoming messages on an *odd* byte boundary. This system doesn't have any inherent size limitations but is not very efficient for large messages or when messages are sent in very quick succession. */ #include "includes.h" /* the locking database handle */ static TDB_CONTEXT *tdb; static int received_signal; /* change the message version with any incompatible changes in the protocol */ #define MESSAGE_VERSION 1 struct message_rec { int msg_version; int msg_type; pid_t dest; pid_t src; size_t len; }; /* we have a linked list of dispatch handlers */ static struct dispatch_fns { struct dispatch_fns *next, *prev; int msg_type; void (*fn)(int msg_type, pid_t pid, void *buf, size_t len); } *dispatch_fns; /**************************************************************************** Notifications come in as signals. ****************************************************************************/ static void sig_usr1(void) { received_signal = 1; sys_select_signal(); } /**************************************************************************** A useful function for testing the message system. ****************************************************************************/ static void ping_message(int msg_type, pid_t src, void *buf, size_t len) { const char *msg = buf ? buf : "none"; DEBUG(1,("INFO: Received PING message from PID %u [%s]\n",(unsigned int)src, msg)); message_send_pid(src, MSG_PONG, buf, len, True); } /**************************************************************************** Initialise the messaging functions. ****************************************************************************/ BOOL message_init(void) { if (tdb) return True; tdb = tdb_open_log(lock_path("messages.tdb"), 0, TDB_CLEAR_IF_FIRST|TDB_DEFAULT, O_RDWR|O_CREAT,0600); if (!tdb) { DEBUG(0,("ERROR: Failed to initialise messages database\n")); return False; } CatchSignal(SIGUSR1, SIGNAL_CAST sig_usr1); message_register(MSG_PING, ping_message); /* Register some debugging related messages */ register_msg_pool_usage(); register_dmalloc_msgs(); return True; } /******************************************************************* Form a static tdb key from a pid. ******************************************************************/ static TDB_DATA message_key_pid(pid_t pid) { static char key[20]; TDB_DATA kbuf; slprintf(key, sizeof(key)-1, "PID/%d", (int)pid); kbuf.dptr = (char *)key; kbuf.dsize = strlen(key)+1; return kbuf; } /**************************************************************************** Notify a process that it has a message. If the process doesn't exist then delete its record in the database. ****************************************************************************/ static BOOL message_notify(pid_t pid) { /* * Doing kill with a non-positive pid causes messages to be * sent to places we don't want. */ SMB_ASSERT(pid > 0); if (kill(pid, SIGUSR1) == -1) { if (errno == ESRCH) { DEBUG(2,("pid %d doesn't exist - deleting messages record\n", (int)pid)); tdb_delete(tdb, message_key_pid(pid)); } else { DEBUG(2,("message to process %d failed - %s\n", (int)pid, strerror(errno))); } return False; } return True; } /**************************************************************************** Send a message to a particular pid. ****************************************************************************/ static BOOL message_send_pid_internal(pid_t pid, int msg_type, const void *buf, size_t len, BOOL duplicates_allowed, unsigned int timeout) { TDB_DATA kbuf; TDB_DATA dbuf; TDB_DATA old_dbuf; struct message_rec rec; char *ptr; struct message_rec prec; /* * Doing kill with a non-positive pid causes messages to be * sent to places we don't want. */ SMB_ASSERT(pid > 0); rec.msg_version = MESSAGE_VERSION; rec.msg_type = msg_type; rec.dest = pid; rec.src = sys_getpid(); rec.len = len; kbuf = message_key_pid(pid); dbuf.dptr = (void *)malloc(len + sizeof(rec)); if (!dbuf.dptr) return False; memcpy(dbuf.dptr, &rec, sizeof(rec)); if (len > 0) memcpy((void *)((char*)dbuf.dptr+sizeof(rec)), buf, len); dbuf.dsize = len + sizeof(rec); if (duplicates_allowed) { /* If duplicates are allowed we can just append the message and return. */ /* lock the record for the destination */ if (timeout) { if (tdb_chainlock_with_timeout(tdb, kbuf, timeout) == -1) { DEBUG(0,("message_send_pid_internal: failed to get chainlock with timeout %ul.\n", timeout)); return False; } } else { if (tdb_chainlock(tdb, kbuf) == -1) { DEBUG(0,("message_send_pid_internal: failed to get chainlock.\n")); return False; } } tdb_append(tdb, kbuf, dbuf); tdb_chainunlock(tdb, kbuf); SAFE_FREE(dbuf.dptr); errno = 0; /* paranoia */ return message_notify(pid); } /* lock the record for the destination */ if (timeout) { if (tdb_chainlock_with_timeout(tdb, kbuf, timeout) == -1) { DEBUG(0,("message_send_pid_internal: failed to get chainlock with timeout %ul.\n", timeout)); return False; } } else { if (tdb_chainlock(tdb, kbuf) == -1) { DEBUG(0,("message_send_pid_internal: failed to get chainlock.\n")); return False; } } old_dbuf = tdb_fetch(tdb, kbuf); if (!old_dbuf.dptr) { /* its a new record */ tdb_store(tdb, kbuf, dbuf, TDB_REPLACE); tdb_chainunlock(tdb, kbuf); SAFE_FREE(dbuf.dptr); errno = 0; /* paranoia */ return message_notify(pid); } /* Not a new record. Check for duplicates. */ for(ptr = (char *)old_dbuf.dptr; ptr < old_dbuf.dptr + old_dbuf.dsize; ) { /* * First check if the message header matches, then, if it's a non-zero * sized message, check if the data matches. If so it's a duplicate and * we can discard it. JRA. */ if (!memcmp(ptr, &rec, sizeof(rec))) { if (!len || (len && !memcmp( ptr + sizeof(rec), buf, len))) { tdb_chainunlock(tdb, kbuf); DEBUG(10,("message_send_pid_internal: discarding duplicate message.\n")); SAFE_FREE(dbuf.dptr); SAFE_FREE(old_dbuf.dptr); return True; } } memcpy(&prec, ptr, sizeof(prec)); ptr += sizeof(rec) + prec.len; } /* we're adding to an existing entry */ tdb_append(tdb, kbuf, dbuf); tdb_chainunlock(tdb, kbuf); SAFE_FREE(old_dbuf.dptr); SAFE_FREE(dbuf.dptr); errno = 0; /* paranoia */ return message_notify(pid); } /**************************************************************************** Send a message to a particular pid - no timeout. ****************************************************************************/ BOOL message_send_pid(pid_t pid, int msg_type, const void *buf, size_t len, BOOL duplicates_allowed) { return message_send_pid_internal(pid, msg_type, buf, len, duplicates_allowed, 0); } /**************************************************************************** Send a message to a particular pid, with timeout in seconds. ****************************************************************************/ BOOL message_send_pid_with_timeout(pid_t pid, int msg_type, const void *buf, size_t len, BOOL duplicates_allowed, unsigned int timeout) { return message_send_pid_internal(pid, msg_type, buf, len, duplicates_allowed, timeout); } /**************************************************************************** Count the messages pending for a particular pid. Expensive.... ****************************************************************************/ unsigned int messages_pending_for_pid(pid_t pid) { TDB_DATA kbuf; TDB_DATA dbuf; char *buf; unsigned int message_count = 0; kbuf = message_key_pid(sys_getpid()); dbuf = tdb_fetch(tdb, kbuf); if (dbuf.dptr == NULL || dbuf.dsize == 0) { SAFE_FREE(dbuf.dptr); return 0; } for (buf = dbuf.dptr; dbuf.dsize > sizeof(struct message_rec);) { struct message_rec rec; memcpy(&rec, buf, sizeof(rec)); buf += (sizeof(rec) + rec.len); dbuf.dsize -= (sizeof(rec) + rec.len); message_count++; } SAFE_FREE(dbuf.dptr); return message_count; } /**************************************************************************** Retrieve all messages for the current process. ****************************************************************************/ static BOOL retrieve_all_messages(char **msgs_buf, size_t *total_len) { TDB_DATA kbuf; TDB_DATA dbuf; TDB_DATA null_dbuf; ZERO_STRUCT(null_dbuf); *msgs_buf = NULL; *total_len = 0; kbuf = message_key_pid(sys_getpid()); if (tdb_chainlock(tdb, kbuf) == -1) return False; dbuf = tdb_fetch(tdb, kbuf); /* * Replace with an empty record to keep the allocated * space in the tdb. */ tdb_store(tdb, kbuf, null_dbuf, TDB_REPLACE); tdb_chainunlock(tdb, kbuf); if (dbuf.dptr == NULL || dbuf.dsize == 0) { SAFE_FREE(dbuf.dptr); return False; } *msgs_buf = dbuf.dptr; *total_len = dbuf.dsize; return True; } /**************************************************************************** Parse out the next message for the current process. ****************************************************************************/ static BOOL message_recv(char *msgs_buf, size_t total_len, int *msg_type, pid_t *src, char **buf, size_t *len) { struct message_rec rec; char *ret_buf = *buf; *buf = NULL; *len = 0; if (total_len - (ret_buf - msgs_buf) < sizeof(rec)) return False; memcpy(&rec, ret_buf, sizeof(rec)); ret_buf += sizeof(rec); if (rec.msg_version != MESSAGE_VERSION) { DEBUG(0,("message version %d received (expected %d)\n", rec.msg_version, MESSAGE_VERSION)); return False; } if (rec.len > 0) { if (total_len - (ret_buf - msgs_buf) < rec.len) return False; } *len = rec.len; *msg_type = rec.msg_type; *src = rec.src; *buf = ret_buf; return True; } /**************************************************************************** Receive and dispatch any messages pending for this process. Notice that all dispatch handlers for a particular msg_type get called, so you can register multiple handlers for a message. *NOTE*: Dispatch functions must be able to cope with incoming messages on an *odd* byte boundary. ****************************************************************************/ void message_dispatch(void) { int msg_type; pid_t src; char *buf; char *msgs_buf; size_t len, total_len; struct dispatch_fns *dfn; int n_handled; if (!received_signal) return; DEBUG(10,("message_dispatch: received_signal = %d\n", received_signal)); received_signal = 0; if (!retrieve_all_messages(&msgs_buf, &total_len)) return; for (buf = msgs_buf; message_recv(msgs_buf, total_len, &msg_type, &src, &buf, &len); buf += len) { DEBUG(10,("message_dispatch: received msg_type=%d src_pid=%u\n", msg_type, (unsigned int) src)); n_handled = 0; for (dfn = dispatch_fns; dfn; dfn = dfn->next) { if (dfn->msg_type == msg_type) { DEBUG(10,("message_dispatch: processing message of type %d.\n", msg_type)); dfn->fn(msg_type, src, len ? (void *)buf : NULL, len); n_handled++; } } if (!n_handled) { DEBUG(5,("message_dispatch: warning: no handlers registed for " "msg_type %d in pid %u\n", msg_type, (unsigned int)sys_getpid())); } } SAFE_FREE(msgs_buf); } /**************************************************************************** Register a dispatch function for a particular message type. *NOTE*: Dispatch functions must be able to cope with incoming messages on an *odd* byte boundary. ****************************************************************************/ void message_register(int msg_type, void (*fn)(int msg_type, pid_t pid, void *buf, size_t len)) { struct dispatch_fns *dfn; dfn = (struct dispatch_fns *)malloc(sizeof(*dfn)); if (dfn != NULL) { ZERO_STRUCTPN(dfn); dfn->msg_type = msg_type; dfn->fn = fn; DLIST_ADD(dispatch_fns, dfn); } else { DEBUG(0,("message_register: Not enough memory. malloc failed!\n")); } } /**************************************************************************** De-register the function for a particular message type. ****************************************************************************/ void message_deregister(int msg_type) { struct dispatch_fns *dfn, *next; for (dfn = dispatch_fns; dfn; dfn = next) { next = dfn->next; if (dfn->msg_type == msg_type) { DLIST_REMOVE(dispatch_fns, dfn); SAFE_FREE(dfn); } } } struct msg_all { int msg_type; uint32 msg_flag; const void *buf; size_t len; BOOL duplicates; int n_sent; }; /**************************************************************************** Send one of the messages for the broadcast. ****************************************************************************/ static int traverse_fn(TDB_CONTEXT *the_tdb, TDB_DATA kbuf, TDB_DATA dbuf, void *state) { struct connections_data crec; struct msg_all *msg_all = (struct msg_all *)state; if (dbuf.dsize != sizeof(crec)) return 0; memcpy(&crec, dbuf.dptr, sizeof(crec)); if (crec.cnum != -1) return 0; /* Don't send if the receiver hasn't registered an interest. */ if(!(crec.bcast_msg_flags & msg_all->msg_flag)) return 0; /* If the msg send fails because the pid was not found (i.e. smbd died), * the msg has already been deleted from the messages.tdb.*/ if (!message_send_pid(crec.pid, msg_all->msg_type, msg_all->buf, msg_all->len, msg_all->duplicates)) { /* If the pid was not found delete the entry from connections.tdb */ if (errno == ESRCH) { DEBUG(2,("pid %u doesn't exist - deleting connections %d [%s]\n", (unsigned int)crec.pid, crec.cnum, crec.name)); tdb_delete(the_tdb, kbuf); } } msg_all->n_sent++; return 0; } /** * Send a message to all smbd processes. * * It isn't very efficient, but should be OK for the sorts of * applications that use it. When we need efficient broadcast we can add * it. * * @param n_sent Set to the number of messages sent. This should be * equal to the number of processes, but be careful for races. * * @retval True for success. **/ BOOL message_send_all(TDB_CONTEXT *conn_tdb, int msg_type, const void *buf, size_t len, BOOL duplicates_allowed, int *n_sent) { struct msg_all msg_all; msg_all.msg_type = msg_type; if (msg_type < 1000) msg_all.msg_flag = FLAG_MSG_GENERAL; else if (msg_type > 1000 && msg_type < 2000) msg_all.msg_flag = FLAG_MSG_NMBD; else if (msg_type > 2000 && msg_type < 2100) msg_all.msg_flag = FLAG_MSG_PRINT_NOTIFY; else if (msg_type > 2100 && msg_type < 3000) msg_all.msg_flag = FLAG_MSG_PRINT_GENERAL; else if (msg_type > 3000 && msg_type < 4000) msg_all.msg_flag = FLAG_MSG_SMBD; else return False; msg_all.buf = buf; msg_all.len = len; msg_all.duplicates = duplicates_allowed; msg_all.n_sent = 0; tdb_traverse(conn_tdb, traverse_fn, &msg_all); if (n_sent) *n_sent = msg_all.n_sent; return True; } /** @} **/