/* * ipc.c - Interprocess communication routines. Handlers read and write. * * Copyright (c) 2001-2006, NLnet Labs. All rights reserved. * * See LICENSE for the license. * */ #include "config.h" #include #include #include #include #include "ipc.h" #include "buffer.h" #include "xfrd-tcp.h" #include "nsd.h" #include "namedb.h" #include "xfrd.h" #include "xfrd-notify.h" #include "difffile.h" #include "rrl.h" /* attempt to send NSD_STATS command to child fd */ static void send_stat_to_child(struct main_ipc_handler_data* data, int fd); /* send reload request over the IPC channel */ static void xfrd_send_reload_req(xfrd_state_type* xfrd); /* send quit request over the IPC channel */ static void xfrd_send_quit_req(xfrd_state_type* xfrd); /* perform read part of handle ipc for xfrd */ static void xfrd_handle_ipc_read(struct event* handler, xfrd_state_type* xfrd); static void ipc_child_quit(struct nsd* nsd) ATTR_NORETURN; static void ipc_child_quit(struct nsd* nsd) { /* call shutdown and quit routines */ nsd->mode = NSD_QUIT; service_remaining_tcp(nsd); #ifdef BIND8_STATS bind8_stats(nsd); #endif /* BIND8_STATS */ #ifdef MEMCLEAN /* OS collects memory pages */ #ifdef RATELIMIT rrl_deinit(nsd->this_child->child_num); #endif event_base_free(nsd->event_base); region_destroy(nsd->server_region); #endif server_shutdown(nsd); /* ENOTREACH */ exit(0); } void child_handle_parent_command(int fd, short event, void* arg) { sig_atomic_t mode; int len; struct ipc_handler_conn_data *data = (struct ipc_handler_conn_data *) arg; if (!(event & EV_READ)) { return; } if ((len = read(fd, &mode, sizeof(mode))) == -1) { log_msg(LOG_ERR, "handle_parent_command: read: %s", strerror(errno)); return; } if (len == 0) { /* parent closed the connection. Quit */ ipc_child_quit(data->nsd); return; } switch (mode) { case NSD_STATS: data->nsd->mode = mode; break; case NSD_QUIT: ipc_child_quit(data->nsd); break; case NSD_QUIT_CHILD: /* close our listening sockets and ack */ server_close_all_sockets(data->nsd->udp, data->nsd->ifs); server_close_all_sockets(data->nsd->tcp, data->nsd->ifs); /* mode == NSD_QUIT_CHILD */ if(write(fd, &mode, sizeof(mode)) == -1) { VERBOSITY(3, (LOG_INFO, "quit child write: %s", strerror(errno))); } ipc_child_quit(data->nsd); break; default: log_msg(LOG_ERR, "handle_parent_command: bad mode %d", (int) mode); break; } } void parent_handle_xfrd_command(netio_type *ATTR_UNUSED(netio), netio_handler_type *handler, netio_event_types_type event_types) { sig_atomic_t mode; int len; struct ipc_handler_conn_data *data = (struct ipc_handler_conn_data *) handler->user_data; if (!(event_types & NETIO_EVENT_READ)) { return; } if ((len = read(handler->fd, &mode, sizeof(mode))) == -1) { log_msg(LOG_ERR, "handle_xfrd_command: read: %s", strerror(errno)); return; } if (len == 0) { /* xfrd closed, we must quit */ DEBUG(DEBUG_IPC,1, (LOG_INFO, "handle_xfrd_command: xfrd closed channel.")); close(handler->fd); handler->fd = -1; data->nsd->mode = NSD_SHUTDOWN; return; } switch (mode) { case NSD_RELOAD: DEBUG(DEBUG_IPC,1, (LOG_INFO, "parent handle xfrd command RELOAD")); data->nsd->signal_hint_reload = 1; break; case NSD_QUIT: case NSD_SHUTDOWN: data->nsd->mode = mode; break; case NSD_STATS: data->nsd->signal_hint_stats = 1; break; case NSD_REAP_CHILDREN: data->nsd->signal_hint_child = 1; break; default: log_msg(LOG_ERR, "handle_xfrd_command: bad mode %d", (int) mode); break; } } static void send_stat_to_child(struct main_ipc_handler_data* data, int fd) { sig_atomic_t cmd = NSD_STATS; if(write(fd, &cmd, sizeof(cmd)) == -1) { if(errno == EAGAIN || errno == EINTR) return; /* try again later */ log_msg(LOG_ERR, "svrmain: problems sending stats to child %d command: %s", (int)data->child->pid, strerror(errno)); return; } data->child->need_to_send_STATS = 0; } #ifndef NDEBUG int packet_read_query_section(buffer_type *packet, uint8_t* dest, uint16_t* qtype, uint16_t* qclass); static void debug_print_fwd_name(int ATTR_UNUSED(len), buffer_type* packet, int acl_num) { uint8_t qnamebuf[MAXDOMAINLEN]; uint16_t qtype, qclass; const dname_type* dname; region_type* tempregion = region_create(xalloc, free); size_t bufpos = buffer_position(packet); buffer_rewind(packet); buffer_skip(packet, 12); if(packet_read_query_section(packet, qnamebuf, &qtype, &qclass)) { dname = dname_make(tempregion, qnamebuf, 1); log_msg(LOG_INFO, "main: fwd packet for %s, acl %d", dname_to_string(dname,0), acl_num); } else { log_msg(LOG_INFO, "main: fwd packet badqname, acl %d", acl_num); } buffer_set_position(packet, bufpos); region_destroy(tempregion); } #endif static void send_quit_to_child(struct main_ipc_handler_data* data, int fd) { sig_atomic_t cmd = NSD_QUIT; if(write(fd, &cmd, sizeof(cmd)) == -1) { if(errno == EAGAIN || errno == EINTR) return; /* try again later */ log_msg(LOG_ERR, "svrmain: problems sending quit to child %d command: %s", (int)data->child->pid, strerror(errno)); return; } data->child->need_to_send_QUIT = 0; DEBUG(DEBUG_IPC,2, (LOG_INFO, "main: sent quit to child %d", (int)data->child->pid)); } /** the child is done, mark it as exited */ static void child_is_done(struct nsd* nsd, int fd) { size_t i; if(fd != -1) close(fd); for(i=0; ichild_count; ++i) if(nsd->children[i].child_fd == fd) { nsd->children[i].child_fd = -1; nsd->children[i].handler->fd = -1; if(nsd->children[i].need_to_exit) { DEBUG(DEBUG_IPC,1, (LOG_INFO, "server %d is done", (int)nsd->children[i].pid)); nsd->children[i].has_exited = 1; } else { log_msg(LOG_WARNING, "server %d died unexpectedly, restarting", (int)nsd->children[i].pid); /* this child is now going to be re-forked as * a subprocess of this server-main, and if a * reload is in progress the other children * are subprocesses of reload. Until the * reload is done and they are all reforked. */ nsd->children[i].pid = -1; nsd->restart_children = 1; } } parent_check_all_children_exited(nsd); } #ifdef BIND8_STATS /** add stats to total */ void stats_add(struct nsdst* total, struct nsdst* s) { unsigned i; for(i=0; iqtype)/sizeof(stc_type); i++) total->qtype[i] += s->qtype[i]; for(i=0; iqclass)/sizeof(stc_type); i++) total->qclass[i] += s->qclass[i]; total->qudp += s->qudp; total->qudp6 += s->qudp6; total->ctcp += s->ctcp; total->ctcp6 += s->ctcp6; total->ctls += s->ctls; total->ctls6 += s->ctls6; for(i=0; ircode)/sizeof(stc_type); i++) total->rcode[i] += s->rcode[i]; for(i=0; iopcode)/sizeof(stc_type); i++) total->opcode[i] += s->opcode[i]; total->dropped += s->dropped; total->truncated += s->truncated; total->wrongzone += s->wrongzone; total->txerr += s->txerr; total->rxerr += s->rxerr; total->edns += s->edns; total->ednserr += s->ednserr; total->raxfr += s->raxfr; total->nona += s->nona; total->rixfr += s->rixfr; total->db_disk = s->db_disk; total->db_mem = s->db_mem; } /** subtract stats from total */ void stats_subtract(struct nsdst* total, struct nsdst* s) { unsigned i; for(i=0; iqtype)/sizeof(stc_type); i++) total->qtype[i] -= s->qtype[i]; for(i=0; iqclass)/sizeof(stc_type); i++) total->qclass[i] -= s->qclass[i]; total->qudp -= s->qudp; total->qudp6 -= s->qudp6; total->ctcp -= s->ctcp; total->ctcp6 -= s->ctcp6; total->ctls -= s->ctls; total->ctls6 -= s->ctls6; for(i=0; ircode)/sizeof(stc_type); i++) total->rcode[i] -= s->rcode[i]; for(i=0; iopcode)/sizeof(stc_type); i++) total->opcode[i] -= s->opcode[i]; total->dropped -= s->dropped; total->truncated -= s->truncated; total->wrongzone -= s->wrongzone; total->txerr -= s->txerr; total->rxerr -= s->rxerr; total->edns -= s->edns; total->ednserr -= s->ednserr; total->raxfr -= s->raxfr; total->nona -= s->nona; total->rixfr -= s->rixfr; } #endif /* BIND8_STATS */ void parent_handle_child_command(netio_type *ATTR_UNUSED(netio), netio_handler_type *handler, netio_event_types_type event_types) { sig_atomic_t mode; int len; struct main_ipc_handler_data *data = (struct main_ipc_handler_data*)handler->user_data; /* do a nonblocking write to the child if it is ready. */ if (event_types & NETIO_EVENT_WRITE) { if(data->child->need_to_send_STATS && !data->child->need_to_exit) { send_stat_to_child(data, handler->fd); } else if(data->child->need_to_send_QUIT) { send_quit_to_child(data, handler->fd); if(!data->child->need_to_send_QUIT) handler->event_types = NETIO_EVENT_READ; } else { handler->event_types = NETIO_EVENT_READ; } } if (!(event_types & NETIO_EVENT_READ)) { return; } if (data->forward_mode) { int got_acl; /* forward the data to xfrd */ DEBUG(DEBUG_IPC,2, (LOG_INFO, "main passed packet readup %d", (int)data->got_bytes)); if(data->got_bytes < sizeof(data->total_bytes)) { if ((len = read(handler->fd, (char*)&data->total_bytes+data->got_bytes, sizeof(data->total_bytes)-data->got_bytes)) == -1) { log_msg(LOG_ERR, "handle_child_command: read: %s", strerror(errno)); return; } if(len == 0) { /* EOF */ data->forward_mode = 0; return; } data->got_bytes += len; if(data->got_bytes < sizeof(data->total_bytes)) return; data->total_bytes = ntohs(data->total_bytes); buffer_clear(data->packet); if(data->total_bytes > buffer_capacity(data->packet)) { log_msg(LOG_ERR, "internal error: ipc too large"); exit(1); } return; } /* read the packet */ if(data->got_bytes-sizeof(data->total_bytes) < data->total_bytes) { if((len = read(handler->fd, buffer_current(data->packet), data->total_bytes - (data->got_bytes-sizeof(data->total_bytes)) )) == -1 ) { log_msg(LOG_ERR, "handle_child_command: read: %s", strerror(errno)); return; } if(len == 0) { /* EOF */ data->forward_mode = 0; return; } data->got_bytes += len; buffer_skip(data->packet, len); /* read rest later */ return; } /* read the acl numbers */ got_acl = data->got_bytes - sizeof(data->total_bytes) - data->total_bytes; if((len = read(handler->fd, (char*)&data->acl_num+got_acl, sizeof(data->acl_num)+sizeof(data->acl_xfr)-got_acl)) == -1 ) { log_msg(LOG_ERR, "handle_child_command: read: %s", strerror(errno)); return; } if(len == 0) { /* EOF */ data->forward_mode = 0; return; } got_acl += len; data->got_bytes += len; if(got_acl >= (int)(sizeof(data->acl_num)+sizeof(data->acl_xfr))) { uint16_t len = htons(data->total_bytes); DEBUG(DEBUG_IPC,2, (LOG_INFO, "main fwd passed packet write %d", (int)data->got_bytes)); #ifndef NDEBUG if(nsd_debug_level >= 2) debug_print_fwd_name(len, data->packet, data->acl_num); #endif data->forward_mode = 0; mode = NSD_PASS_TO_XFRD; if(!write_socket(*data->xfrd_sock, &mode, sizeof(mode)) || !write_socket(*data->xfrd_sock, &len, sizeof(len)) || !write_socket(*data->xfrd_sock, buffer_begin(data->packet), data->total_bytes) || !write_socket(*data->xfrd_sock, &data->acl_num, sizeof(data->acl_num)) || !write_socket(*data->xfrd_sock, &data->acl_xfr, sizeof(data->acl_xfr))) { log_msg(LOG_ERR, "error in ipc fwd main2xfrd: %s", strerror(errno)); } } return; } /* read command from ipc */ if ((len = read(handler->fd, &mode, sizeof(mode))) == -1) { log_msg(LOG_ERR, "handle_child_command: read: %s", strerror(errno)); return; } if (len == 0) { child_is_done(data->nsd, handler->fd); return; } switch (mode) { case NSD_QUIT: data->nsd->mode = mode; break; case NSD_STATS: data->nsd->signal_hint_stats = 1; break; case NSD_REAP_CHILDREN: data->nsd->signal_hint_child = 1; break; case NSD_PASS_TO_XFRD: /* set mode for handle_child_command; echo to xfrd. */ data->forward_mode = 1; data->got_bytes = 0; data->total_bytes = 0; break; default: log_msg(LOG_ERR, "handle_child_command: bad mode %d", (int) mode); break; } } void parent_check_all_children_exited(struct nsd* nsd) { size_t i; for(i=0; i < nsd->child_count; i++) { if(!nsd->children[i].need_to_exit) return; if(!nsd->children[i].has_exited) return; } nsd->mode = NSD_QUIT_SYNC; DEBUG(DEBUG_IPC,2, (LOG_INFO, "main: all children exited. quit sync.")); } void parent_handle_reload_command(netio_type *ATTR_UNUSED(netio), netio_handler_type *handler, netio_event_types_type event_types) { sig_atomic_t mode; int len; size_t i; struct nsd *nsd = (struct nsd*) handler->user_data; if (!(event_types & NETIO_EVENT_READ)) { return; } /* read command from ipc */ if ((len = read(handler->fd, &mode, sizeof(mode))) == -1) { log_msg(LOG_ERR, "handle_reload_command: read: %s", strerror(errno)); return; } if (len == 0) { assert(handler->fd != -1); /* or read() would have failed */ close(handler->fd); handler->fd = -1; log_msg(LOG_ERR, "handle_reload_cmd: reload closed cmd channel"); nsd->reload_failed = 1; return; } switch (mode) { case NSD_QUIT_SYNC: /* set all children to exit, only then notify xfrd. */ /* so that buffered packets to pass to xfrd can arrive. */ for(i=0; i < nsd->child_count; i++) { nsd->children[i].need_to_exit = 1; if(nsd->children[i].pid > 0 && nsd->children[i].child_fd != -1) { nsd->children[i].need_to_send_QUIT = 1; nsd->children[i].handler->event_types |= NETIO_EVENT_WRITE; } else { if(nsd->children[i].child_fd == -1) nsd->children[i].has_exited = 1; } } parent_check_all_children_exited(nsd); break; default: log_msg(LOG_ERR, "handle_reload_command: bad mode %d", (int) mode); break; } } static void xfrd_send_reload_req(xfrd_state_type* xfrd) { sig_atomic_t req = NSD_RELOAD; uint64_t p = xfrd->last_task->data; udb_ptr_unlink(xfrd->last_task, xfrd->nsd->task[xfrd->nsd->mytask]); task_process_sync(xfrd->nsd->task[xfrd->nsd->mytask]); /* ask server_main for a reload */ if(write(xfrd->ipc_handler.ev_fd, &req, sizeof(req)) == -1) { udb_ptr_init(xfrd->last_task, xfrd->nsd->task[xfrd->nsd->mytask]); udb_ptr_set(xfrd->last_task, xfrd->nsd->task[xfrd->nsd->mytask], p); if(errno == EAGAIN || errno == EINTR) return; /* try again later */ log_msg(LOG_ERR, "xfrd: problems sending reload command: %s", strerror(errno)); return; } DEBUG(DEBUG_IPC,1, (LOG_INFO, "xfrd: asked nsd to reload new updates")); /* swapped task to other side, start to use other task udb. */ xfrd->nsd->mytask = 1 - xfrd->nsd->mytask; task_remap(xfrd->nsd->task[xfrd->nsd->mytask]); udb_ptr_init(xfrd->last_task, xfrd->nsd->task[xfrd->nsd->mytask]); assert(udb_base_get_userdata(xfrd->nsd->task[xfrd->nsd->mytask])->data == 0); if(!xfrd->reload_cmd_first_sent) xfrd->reload_cmd_first_sent = xfrd_time(); xfrd->reload_cmd_last_sent = xfrd_time(); xfrd->need_to_send_reload = 0; xfrd->can_send_reload = 0; } void ipc_xfrd_set_listening(struct xfrd_state* xfrd, short mode) { int fd = xfrd->ipc_handler.ev_fd; struct event_base* base = xfrd->event_base; event_del(&xfrd->ipc_handler); memset(&xfrd->ipc_handler, 0, sizeof(xfrd->ipc_handler)); event_set(&xfrd->ipc_handler, fd, mode, xfrd_handle_ipc, xfrd); if(event_base_set(base, &xfrd->ipc_handler) != 0) log_msg(LOG_ERR, "ipc: cannot set event_base"); /* no timeout for IPC events */ if(event_add(&xfrd->ipc_handler, NULL) != 0) log_msg(LOG_ERR, "ipc: cannot add event"); xfrd->ipc_handler_flags = mode; } static void xfrd_send_shutdown_req(xfrd_state_type* xfrd) { sig_atomic_t cmd = NSD_SHUTDOWN; xfrd->ipc_send_blocked = 1; ipc_xfrd_set_listening(xfrd, EV_PERSIST|EV_READ); DEBUG(DEBUG_IPC,1, (LOG_INFO, "xfrd: ipc send shutdown")); if(!write_socket(xfrd->ipc_handler.ev_fd, &cmd, sizeof(cmd))) { log_msg(LOG_ERR, "xfrd: error writing shutdown to main: %s", strerror(errno)); } xfrd->need_to_send_shutdown = 0; } static void xfrd_send_quit_req(xfrd_state_type* xfrd) { sig_atomic_t cmd = NSD_QUIT; xfrd->ipc_send_blocked = 1; ipc_xfrd_set_listening(xfrd, EV_PERSIST|EV_READ); DEBUG(DEBUG_IPC,1, (LOG_INFO, "xfrd: ipc send ackreload(quit)")); if(!write_socket(xfrd->ipc_handler.ev_fd, &cmd, sizeof(cmd))) { log_msg(LOG_ERR, "xfrd: error writing ack to main: %s", strerror(errno)); } xfrd->need_to_send_quit = 0; } static void xfrd_send_stats(xfrd_state_type* xfrd) { sig_atomic_t cmd = NSD_STATS; DEBUG(DEBUG_IPC,1, (LOG_INFO, "xfrd: ipc send stats")); if(!write_socket(xfrd->ipc_handler.ev_fd, &cmd, sizeof(cmd))) { log_msg(LOG_ERR, "xfrd: error writing stats to main: %s", strerror(errno)); } xfrd->need_to_send_stats = 0; } void xfrd_handle_ipc(int ATTR_UNUSED(fd), short event, void* arg) { xfrd_state_type* xfrd = (xfrd_state_type*)arg; if ((event & EV_READ)) { /* first attempt to read as a signal from main * could block further send operations */ xfrd_handle_ipc_read(&xfrd->ipc_handler, xfrd); } if ((event & EV_WRITE)) { if(xfrd->ipc_send_blocked) { /* wait for RELOAD_DONE */ ipc_xfrd_set_listening(xfrd, EV_PERSIST|EV_READ); return; } if(xfrd->need_to_send_shutdown) { xfrd_send_shutdown_req(xfrd); } else if(xfrd->need_to_send_quit) { xfrd_send_quit_req(xfrd); } else if(xfrd->can_send_reload && xfrd->need_to_send_reload) { xfrd_send_reload_req(xfrd); } else if(xfrd->need_to_send_stats) { xfrd_send_stats(xfrd); } if(!(xfrd->can_send_reload && xfrd->need_to_send_reload) && !xfrd->need_to_send_shutdown && !xfrd->need_to_send_quit && !xfrd->need_to_send_stats) { /* disable writing for now */ ipc_xfrd_set_listening(xfrd, EV_PERSIST|EV_READ); } } } static void xfrd_handle_ipc_read(struct event* handler, xfrd_state_type* xfrd) { sig_atomic_t cmd; int len; if(xfrd->ipc_conn->is_reading==2) { buffer_type* tmp = xfrd->ipc_pass; uint32_t acl_num; int32_t acl_xfr; /* read acl_num */ int ret = conn_read(xfrd->ipc_conn); if(ret == -1) { log_msg(LOG_ERR, "xfrd: error in read ipc: %s", strerror(errno)); xfrd->ipc_conn->is_reading = 0; return; } if(ret == 0) return; buffer_flip(xfrd->ipc_conn->packet); xfrd->ipc_pass = xfrd->ipc_conn->packet; xfrd->ipc_conn->packet = tmp; xfrd->ipc_conn->is_reading = 0; acl_num = buffer_read_u32(xfrd->ipc_pass); acl_xfr = (int32_t)buffer_read_u32(xfrd->ipc_pass); xfrd_handle_passed_packet(xfrd->ipc_conn->packet, acl_num, acl_xfr); return; } if(xfrd->ipc_conn->is_reading) { /* reading an IPC message */ buffer_type* tmp; int ret = conn_read(xfrd->ipc_conn); if(ret == -1) { log_msg(LOG_ERR, "xfrd: error in read ipc: %s", strerror(errno)); xfrd->ipc_conn->is_reading = 0; return; } if(ret == 0) return; buffer_flip(xfrd->ipc_conn->packet); /* use ipc_conn to read remaining data as well */ tmp = xfrd->ipc_pass; xfrd->ipc_conn->is_reading=2; xfrd->ipc_pass = xfrd->ipc_conn->packet; xfrd->ipc_conn->packet = tmp; xfrd->ipc_conn->total_bytes = sizeof(xfrd->ipc_conn->msglen); xfrd->ipc_conn->msglen = 2*sizeof(uint32_t); buffer_clear(xfrd->ipc_conn->packet); buffer_set_limit(xfrd->ipc_conn->packet, xfrd->ipc_conn->msglen); return; } if((len = read(handler->ev_fd, &cmd, sizeof(cmd))) == -1) { if(errno != EINTR && errno != EAGAIN) log_msg(LOG_ERR, "xfrd_handle_ipc: read: %s", strerror(errno)); return; } if(len == 0) { /* parent closed the connection. Quit */ DEBUG(DEBUG_IPC,1, (LOG_INFO, "xfrd: main closed connection.")); xfrd->shutdown = 1; return; } switch(cmd) { case NSD_QUIT: case NSD_SHUTDOWN: DEBUG(DEBUG_IPC,1, (LOG_INFO, "xfrd: main sent shutdown cmd.")); xfrd->shutdown = 1; break; case NSD_RELOAD_FAILED: xfrd->reload_failed = 1; /* fall through */ case NSD_RELOAD_DONE: /* reload has finished */ DEBUG(DEBUG_IPC,1, (LOG_INFO, "xfrd: ipc recv %s", xfrd->reload_failed ? "RELOAD FAILED" : "RELOAD DONE")); if(block_read(NULL, handler->ev_fd, &xfrd->reload_pid, sizeof(pid_t), -1) != sizeof(pid_t)) { log_msg(LOG_ERR, "xfrd cannot get reload_pid"); } /* read the not-mytask for the results and soainfo */ xfrd_process_task_result(xfrd, xfrd->nsd->task[1-xfrd->nsd->mytask]); /* reset the IPC, (and the nonblocking ipc write; the new parent does not want half a packet) */ xfrd->can_send_reload = 1; xfrd->ipc_send_blocked = 0; ipc_xfrd_set_listening(xfrd, EV_PERSIST|EV_READ|EV_WRITE); xfrd_reopen_logfile(); if(!xfrd->reload_failed) { xfrd_check_failed_updates(); xfrd->reload_cmd_first_sent = 0; } else { /* make reload happen again, right away */ xfrd_set_reload_now(xfrd); } xfrd_prepare_zones_for_reload(); xfrd->reload_failed = 0; break; case NSD_PASS_TO_XFRD: DEBUG(DEBUG_IPC,1, (LOG_INFO, "xfrd: ipc recv PASS_TO_XFRD")); xfrd->ipc_conn->is_reading = 1; break; case NSD_RELOAD_REQ: DEBUG(DEBUG_IPC,1, (LOG_INFO, "xfrd: ipc recv RELOAD_REQ")); /* make reload happen, right away, and schedule file check */ task_new_check_zonefiles(xfrd->nsd->task[xfrd->nsd->mytask], xfrd->last_task, NULL); xfrd_set_reload_now(xfrd); break; case NSD_RELOAD: /* main tells us that reload is done, stop ipc send to main */ DEBUG(DEBUG_IPC,1, (LOG_INFO, "xfrd: ipc recv RELOAD")); ipc_xfrd_set_listening(xfrd, EV_PERSIST|EV_READ|EV_WRITE); xfrd->need_to_send_quit = 1; break; default: log_msg(LOG_ERR, "xfrd_handle_ipc: bad mode %d (%d)", (int)cmd, (int)ntohl(cmd)); break; } if(xfrd->ipc_conn->is_reading) { /* setup read of info */ xfrd->ipc_conn->total_bytes = 0; xfrd->ipc_conn->msglen = 0; buffer_clear(xfrd->ipc_conn->packet); } }