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|
/*
* server.c -- nsd(8) network input/output
*
* Copyright (c) 2001-2006, NLnet Labs. All rights reserved.
*
* See LICENSE for the license.
*
*/
#include "config.h"
#include <sys/types.h>
#include <sys/param.h>
#include <sys/socket.h>
#include <sys/uio.h>
#include <sys/wait.h>
#include <netinet/in.h>
#include <arpa/inet.h>
#include <assert.h>
#include <ctype.h>
#include <errno.h>
#include <fcntl.h>
#include <stddef.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <time.h>
#include <unistd.h>
#include <signal.h>
#include <netdb.h>
#ifndef SHUT_WR
#define SHUT_WR 1
#endif
#include <openssl/rand.h>
#ifndef USE_MINI_EVENT
# ifdef HAVE_EVENT_H
# include <event.h>
# else
# include <event2/event.h>
# include "event2/event_struct.h"
# include "event2/event_compat.h"
# endif
#else
# include "mini_event.h"
#endif
#include "axfr.h"
#include "namedb.h"
#include "netio.h"
#include "xfrd.h"
#include "xfrd-tcp.h"
#include "xfrd-disk.h"
#include "difffile.h"
#include "nsec3.h"
#include "ipc.h"
#include "udb.h"
#include "remote.h"
#include "lookup3.h"
#include "rrl.h"
#define RELOAD_SYNC_TIMEOUT 25 /* seconds */
/*
* Data for the UDP handlers.
*/
struct udp_handler_data
{
struct nsd *nsd;
struct nsd_socket *socket;
query_type *query;
};
struct tcp_accept_handler_data {
struct nsd *nsd;
struct nsd_socket *socket;
int event_added;
struct event event;
};
/*
* These globals are used to enable the TCP accept handlers
* when the number of TCP connection drops below the maximum
* number of TCP connections.
*/
static size_t tcp_accept_handler_count;
static struct tcp_accept_handler_data* tcp_accept_handlers;
static struct event slowaccept_event;
static int slowaccept;
#ifndef NONBLOCKING_IS_BROKEN
# define NUM_RECV_PER_SELECT 100
#endif
#if (!defined(NONBLOCKING_IS_BROKEN) && defined(HAVE_RECVMMSG))
struct mmsghdr msgs[NUM_RECV_PER_SELECT];
struct iovec iovecs[NUM_RECV_PER_SELECT];
struct query *queries[NUM_RECV_PER_SELECT];
#endif
/*
* Data for the TCP connection handlers.
*
* The TCP handlers use non-blocking I/O. This is necessary to avoid
* blocking the entire server on a slow TCP connection, but does make
* reading from and writing to the socket more complicated.
*
* Basically, whenever a read/write would block (indicated by the
* EAGAIN errno variable) we remember the position we were reading
* from/writing to and return from the TCP reading/writing event
* handler. When the socket becomes readable/writable again we
* continue from the same position.
*/
struct tcp_handler_data
{
/*
* The region used to allocate all TCP connection related
* data, including this structure. This region is destroyed
* when the connection is closed.
*/
region_type* region;
/*
* The global nsd structure.
*/
struct nsd* nsd;
/*
* The current query data for this TCP connection.
*/
query_type* query;
/*
* The query_state is used to remember if we are performing an
* AXFR, if we're done processing, or if we should discard the
* query and connection.
*/
query_state_type query_state;
/*
* The event for the file descriptor and tcp timeout
*/
struct event event;
/*
* The bytes_transmitted field is used to remember the number
* of bytes transmitted when receiving or sending a DNS
* packet. The count includes the two additional bytes used
* to specify the packet length on a TCP connection.
*/
size_t bytes_transmitted;
/*
* The number of queries handled by this specific TCP connection.
*/
int query_count;
};
/*
* Handle incoming queries on the UDP server sockets.
*/
static void handle_udp(int fd, short event, void* arg);
/*
* Handle incoming connections on the TCP sockets. These handlers
* usually wait for the NETIO_EVENT_READ event (indicating an incoming
* connection) but are disabled when the number of current TCP
* connections is equal to the maximum number of TCP connections.
* Disabling is done by changing the handler to wait for the
* NETIO_EVENT_NONE type. This is done using the function
* configure_tcp_accept_handlers.
*/
static void handle_tcp_accept(int fd, short event, void* arg);
/*
* Handle incoming queries on a TCP connection. The TCP connections
* are configured to be non-blocking and the handler may be called
* multiple times before a complete query is received.
*/
static void handle_tcp_reading(int fd, short event, void* arg);
/*
* Handle outgoing responses on a TCP connection. The TCP connections
* are configured to be non-blocking and the handler may be called
* multiple times before a complete response is sent.
*/
static void handle_tcp_writing(int fd, short event, void* arg);
/*
* Send all children the quit nonblocking, then close pipe.
*/
static void send_children_quit(struct nsd* nsd);
/* same, for shutdown time, waits for child to exit to avoid restart issues */
static void send_children_quit_and_wait(struct nsd* nsd);
/* set childrens flags to send NSD_STATS to them */
#ifdef BIND8_STATS
static void set_children_stats(struct nsd* nsd);
#endif /* BIND8_STATS */
/*
* Change the event types the HANDLERS are interested in to EVENT_TYPES.
*/
static void configure_handler_event_types(short event_types);
static uint16_t *compressed_dname_offsets = 0;
static uint32_t compression_table_capacity = 0;
static uint32_t compression_table_size = 0;
/*
* Remove the specified pid from the list of child pids. Returns -1 if
* the pid is not in the list, child_num otherwise. The field is set to 0.
*/
static int
delete_child_pid(struct nsd *nsd, pid_t pid)
{
size_t i;
for (i = 0; i < nsd->child_count; ++i) {
if (nsd->children[i].pid == pid) {
nsd->children[i].pid = 0;
if(!nsd->children[i].need_to_exit) {
if(nsd->children[i].child_fd != -1)
close(nsd->children[i].child_fd);
nsd->children[i].child_fd = -1;
if(nsd->children[i].handler)
nsd->children[i].handler->fd = -1;
}
return i;
}
}
return -1;
}
/*
* Restart child servers if necessary.
*/
static int
restart_child_servers(struct nsd *nsd, region_type* region, netio_type* netio,
int* xfrd_sock_p)
{
struct main_ipc_handler_data *ipc_data;
size_t i;
int sv[2];
/* Fork the child processes... */
for (i = 0; i < nsd->child_count; ++i) {
if (nsd->children[i].pid <= 0) {
if (nsd->children[i].child_fd != -1)
close(nsd->children[i].child_fd);
if (socketpair(AF_UNIX, SOCK_STREAM, 0, sv) == -1) {
log_msg(LOG_ERR, "socketpair: %s",
strerror(errno));
return -1;
}
nsd->children[i].child_fd = sv[0];
nsd->children[i].parent_fd = sv[1];
nsd->children[i].pid = fork();
switch (nsd->children[i].pid) {
default: /* SERVER MAIN */
close(nsd->children[i].parent_fd);
nsd->children[i].parent_fd = -1;
if (fcntl(nsd->children[i].child_fd, F_SETFL, O_NONBLOCK) == -1) {
log_msg(LOG_ERR, "cannot fcntl pipe: %s", strerror(errno));
}
if(!nsd->children[i].handler)
{
ipc_data = (struct main_ipc_handler_data*) region_alloc(
region, sizeof(struct main_ipc_handler_data));
ipc_data->nsd = nsd;
ipc_data->child = &nsd->children[i];
ipc_data->child_num = i;
ipc_data->xfrd_sock = xfrd_sock_p;
ipc_data->packet = buffer_create(region, QIOBUFSZ);
ipc_data->forward_mode = 0;
ipc_data->got_bytes = 0;
ipc_data->total_bytes = 0;
ipc_data->acl_num = 0;
nsd->children[i].handler = (struct netio_handler*) region_alloc(
region, sizeof(struct netio_handler));
nsd->children[i].handler->fd = nsd->children[i].child_fd;
nsd->children[i].handler->timeout = NULL;
nsd->children[i].handler->user_data = ipc_data;
nsd->children[i].handler->event_types = NETIO_EVENT_READ;
nsd->children[i].handler->event_handler = parent_handle_child_command;
netio_add_handler(netio, nsd->children[i].handler);
}
/* clear any ongoing ipc */
ipc_data = (struct main_ipc_handler_data*)
nsd->children[i].handler->user_data;
ipc_data->forward_mode = 0;
/* restart - update fd */
nsd->children[i].handler->fd = nsd->children[i].child_fd;
break;
case 0: /* CHILD */
/* the child need not be able to access the
* nsd.db file */
namedb_close_udb(nsd->db);
nsd->pid = 0;
nsd->child_count = 0;
nsd->server_kind = nsd->children[i].kind;
nsd->this_child = &nsd->children[i];
/* remove signal flags inherited from parent
the parent will handle them. */
nsd->signal_hint_reload_hup = 0;
nsd->signal_hint_reload = 0;
nsd->signal_hint_child = 0;
nsd->signal_hint_quit = 0;
nsd->signal_hint_shutdown = 0;
nsd->signal_hint_stats = 0;
nsd->signal_hint_statsusr = 0;
close(*xfrd_sock_p);
close(nsd->this_child->child_fd);
nsd->this_child->child_fd = -1;
if (fcntl(nsd->this_child->parent_fd, F_SETFL, O_NONBLOCK) == -1) {
log_msg(LOG_ERR, "cannot fcntl pipe: %s", strerror(errno));
}
server_child(nsd);
/* NOTREACH */
exit(0);
case -1:
log_msg(LOG_ERR, "fork failed: %s",
strerror(errno));
return -1;
}
}
}
return 0;
}
#ifdef BIND8_STATS
static void set_bind8_alarm(struct nsd* nsd)
{
/* resync so that the next alarm is on the next whole minute */
if(nsd->st.period > 0) /* % by 0 gives divbyzero error */
alarm(nsd->st.period - (time(NULL) % nsd->st.period));
}
#endif
static void
cleanup_dname_compression_tables(void *ptr)
{
free(ptr);
compressed_dname_offsets = NULL;
compression_table_capacity = 0;
}
static void
initialize_dname_compression_tables(struct nsd *nsd)
{
size_t needed = domain_table_count(nsd->db->domains) + 1;
needed += EXTRA_DOMAIN_NUMBERS;
if(compression_table_capacity < needed) {
if(compressed_dname_offsets) {
region_remove_cleanup(nsd->db->region,
cleanup_dname_compression_tables,
compressed_dname_offsets);
free(compressed_dname_offsets);
}
compressed_dname_offsets = (uint16_t *) xalloc(
needed * sizeof(uint16_t));
region_add_cleanup(nsd->db->region, cleanup_dname_compression_tables,
compressed_dname_offsets);
compression_table_capacity = needed;
compression_table_size=domain_table_count(nsd->db->domains)+1;
}
memset(compressed_dname_offsets, 0, needed * sizeof(uint16_t));
compressed_dname_offsets[0] = QHEADERSZ; /* The original query name */
}
/*
* Initialize the server, create and bind the sockets.
*
*/
int
server_init(struct nsd *nsd)
{
size_t i;
#if defined(SO_REUSEADDR) || (defined(INET6) && (defined(IPV6_V6ONLY) || defined(IPV6_USE_MIN_MTU) || defined(IPV6_MTU) || defined(IP_TRANSPARENT)))
int on = 1;
#endif
/* UDP */
/* Make a socket... */
for (i = 0; i < nsd->ifs; i++) {
if (!nsd->udp[i].addr) {
nsd->udp[i].s = -1;
continue;
}
if ((nsd->udp[i].s = socket(nsd->udp[i].addr->ai_family, nsd->udp[i].addr->ai_socktype, 0)) == -1) {
#if defined(INET6)
if (nsd->udp[i].addr->ai_family == AF_INET6 &&
errno == EAFNOSUPPORT && nsd->grab_ip6_optional) {
log_msg(LOG_WARNING, "fallback to UDP4, no IPv6: not supported");
continue;
}
#endif /* INET6 */
log_msg(LOG_ERR, "can't create a socket: %s", strerror(errno));
return -1;
}
#if defined(SO_RCVBUF) || defined(SO_SNDBUF)
if(1) {
int rcv = 1*1024*1024;
int snd = 1*1024*1024;
#ifdef SO_RCVBUF
# ifdef SO_RCVBUFFORCE
if(setsockopt(nsd->udp[i].s, SOL_SOCKET, SO_RCVBUFFORCE, (void*)&rcv,
(socklen_t)sizeof(rcv)) < 0) {
if(errno != EPERM && errno != ENOBUFS) {
log_msg(LOG_ERR, "setsockopt(..., SO_RCVBUFFORCE, "
"...) failed: %s", strerror(errno));
return -1;
}
# else
if(1) {
# endif /* SO_RCVBUFFORCE */
if(setsockopt(nsd->udp[i].s, SOL_SOCKET, SO_RCVBUF, (void*)&rcv,
(socklen_t)sizeof(rcv)) < 0) {
if(errno != ENOBUFS && errno != ENOSYS) {
log_msg(LOG_ERR, "setsockopt(..., SO_RCVBUF, "
"...) failed: %s", strerror(errno));
return -1;
}
}
}
#endif /* SO_RCVBUF */
#ifdef SO_SNDBUF
# ifdef SO_SNDBUFFORCE
if(setsockopt(nsd->udp[i].s, SOL_SOCKET, SO_SNDBUFFORCE, (void*)&snd,
(socklen_t)sizeof(snd)) < 0) {
if(errno != EPERM && errno != ENOBUFS) {
log_msg(LOG_ERR, "setsockopt(..., SO_SNDBUFFORCE, "
"...) failed: %s", strerror(errno));
return -1;
}
# else
if(1) {
# endif /* SO_SNDBUFFORCE */
if(setsockopt(nsd->udp[i].s, SOL_SOCKET, SO_SNDBUF, (void*)&snd,
(socklen_t)sizeof(snd)) < 0) {
if(errno != ENOBUFS && errno != ENOSYS) {
log_msg(LOG_ERR, "setsockopt(..., SO_SNDBUF, "
"...) failed: %s", strerror(errno));
return -1;
}
}
}
#endif /* SO_SNDBUF */
}
#endif /* defined(SO_RCVBUF) || defined(SO_SNDBUF) */
#if defined(INET6)
if (nsd->udp[i].addr->ai_family == AF_INET6) {
# if defined(IPV6_V6ONLY)
if (setsockopt(nsd->udp[i].s,
IPPROTO_IPV6, IPV6_V6ONLY,
&on, sizeof(on)) < 0)
{
log_msg(LOG_ERR, "setsockopt(..., IPV6_V6ONLY, ...) failed: %s",
strerror(errno));
return -1;
}
# endif
# if defined(IPV6_USE_MIN_MTU)
/*
* There is no fragmentation of IPv6 datagrams
* during forwarding in the network. Therefore
* we do not send UDP datagrams larger than
* the minimum IPv6 MTU of 1280 octets. The
* EDNS0 message length can be larger if the
* network stack supports IPV6_USE_MIN_MTU.
*/
if (setsockopt(nsd->udp[i].s,
IPPROTO_IPV6, IPV6_USE_MIN_MTU,
&on, sizeof(on)) < 0)
{
log_msg(LOG_ERR, "setsockopt(..., IPV6_USE_MIN_MTU, ...) failed: %s",
strerror(errno));
return -1;
}
# elif defined(IPV6_MTU)
/*
* On Linux, PMTUD is disabled by default for datagrams
* so set the MTU equal to the MIN MTU to get the same.
*/
on = IPV6_MIN_MTU;
if (setsockopt(nsd->udp[i].s, IPPROTO_IPV6, IPV6_MTU,
&on, sizeof(on)) < 0)
{
log_msg(LOG_ERR, "setsockopt(..., IPV6_MTU, ...) failed: %s",
strerror(errno));
return -1;
}
on = 1;
# endif
}
#endif
#if defined(AF_INET)
if (nsd->udp[i].addr->ai_family == AF_INET) {
# if defined(IP_MTU_DISCOVER) && defined(IP_PMTUDISC_DONT)
int action = IP_PMTUDISC_DONT;
if (setsockopt(nsd->udp[i].s, IPPROTO_IP,
IP_MTU_DISCOVER, &action, sizeof(action)) < 0)
{
log_msg(LOG_ERR, "setsockopt(..., IP_MTU_DISCOVER, IP_PMTUDISC_DONT...) failed: %s",
strerror(errno));
return -1;
}
# elif defined(IP_DONTFRAG)
int off = 0;
if (setsockopt(nsd->udp[i].s, IPPROTO_IP, IP_DONTFRAG,
&off, sizeof(off)) < 0)
{
log_msg(LOG_ERR, "setsockopt(..., IP_DONTFRAG, ...) failed: %s",
strerror(errno));
return -1;
}
# endif
}
#endif
/* set it nonblocking */
/* otherwise, on OSes with thundering herd problems, the
UDP recv could block NSD after select returns readable. */
if (fcntl(nsd->udp[i].s, F_SETFL, O_NONBLOCK) == -1) {
log_msg(LOG_ERR, "cannot fcntl udp: %s", strerror(errno));
}
/* Bind it... */
if (nsd->options->ip_transparent) {
#ifdef IP_TRANSPARENT
if (setsockopt(nsd->udp[i].s, IPPROTO_IP, IP_TRANSPARENT, &on, sizeof(on)) < 0) {
log_msg(LOG_ERR, "setsockopt(...,IP_TRANSPARENT, ...) failed for udp: %s",
strerror(errno));
}
#endif /* IP_TRANSPARENT */
}
if (bind(nsd->udp[i].s, (struct sockaddr *) nsd->udp[i].addr->ai_addr, nsd->udp[i].addr->ai_addrlen) != 0) {
log_msg(LOG_ERR, "can't bind udp socket: %s", strerror(errno));
return -1;
}
}
/* TCP */
/* Make a socket... */
for (i = 0; i < nsd->ifs; i++) {
if (!nsd->tcp[i].addr) {
nsd->tcp[i].s = -1;
continue;
}
if ((nsd->tcp[i].s = socket(nsd->tcp[i].addr->ai_family, nsd->tcp[i].addr->ai_socktype, 0)) == -1) {
#if defined(INET6)
if (nsd->tcp[i].addr->ai_family == AF_INET6 &&
errno == EAFNOSUPPORT && nsd->grab_ip6_optional) {
log_msg(LOG_WARNING, "fallback to TCP4, no IPv6: not supported");
continue;
}
#endif /* INET6 */
log_msg(LOG_ERR, "can't create a socket: %s", strerror(errno));
return -1;
}
#ifdef SO_REUSEADDR
if (setsockopt(nsd->tcp[i].s, SOL_SOCKET, SO_REUSEADDR, &on, sizeof(on)) < 0) {
log_msg(LOG_ERR, "setsockopt(..., SO_REUSEADDR, ...) failed: %s", strerror(errno));
}
#endif /* SO_REUSEADDR */
#if defined(INET6)
if (nsd->tcp[i].addr->ai_family == AF_INET6) {
# if defined(IPV6_V6ONLY)
if (setsockopt(nsd->tcp[i].s, IPPROTO_IPV6, IPV6_V6ONLY,
&on, sizeof(on)) < 0) {
log_msg(LOG_ERR, "setsockopt(..., IPV6_V6ONLY, ...) failed: %s", strerror(errno));
return -1;
}
# endif
# if defined(IPV6_USE_MIN_MTU)
/*
* Use minimum MTU to minimize delays learning working
* PMTU when communicating through a tunnel.
*/
if (setsockopt(nsd->tcp[i].s,
IPPROTO_IPV6, IPV6_USE_MIN_MTU,
&on, sizeof(on)) < 0) {
log_msg(LOG_ERR, "setsockopt(..., IPV6_USE_MIN_MTU, ...) failed: %s", strerror(errno));
return -1;
}
# elif defined(IPV6_MTU)
/*
* On Linux, PMTUD is disabled by default for datagrams
* so set the MTU equal to the MIN MTU to get the same.
*/
on = IPV6_MIN_MTU;
if (setsockopt(nsd->tcp[i].s, IPPROTO_IPV6, IPV6_MTU,
&on, sizeof(on)) < 0) {
log_msg(LOG_ERR, "setsockopt(..., IPV6_MTU, ...) failed: %s", strerror(errno));
return -1;
}
on = 1;
# endif
}
#endif
/* set it nonblocking */
/* (StevensUNP p463), if tcp listening socket is blocking, then
it may block in accept, even if select() says readable. */
if (fcntl(nsd->tcp[i].s, F_SETFL, O_NONBLOCK) == -1) {
log_msg(LOG_ERR, "cannot fcntl tcp: %s", strerror(errno));
}
/* Bind it... */
if (nsd->options->ip_transparent) {
#ifdef IP_TRANSPARENT
if (setsockopt(nsd->tcp[i].s, IPPROTO_IP, IP_TRANSPARENT, &on, sizeof(on)) < 0) {
log_msg(LOG_ERR, "setsockopt(...,IP_TRANSPARENT, ...) failed for tcp: %s",
strerror(errno));
}
#endif /* IP_TRANSPARENT */
}
if (bind(nsd->tcp[i].s, (struct sockaddr *) nsd->tcp[i].addr->ai_addr, nsd->tcp[i].addr->ai_addrlen) != 0) {
log_msg(LOG_ERR, "can't bind tcp socket: %s", strerror(errno));
return -1;
}
/* Listen to it... */
if (listen(nsd->tcp[i].s, TCP_BACKLOG) == -1) {
log_msg(LOG_ERR, "can't listen: %s", strerror(errno));
return -1;
}
}
return 0;
}
/*
* Prepare the server for take off.
*
*/
int
server_prepare(struct nsd *nsd)
{
#ifdef RATELIMIT
/* set secret modifier for hashing (udb ptr buckets and rate limits) */
#ifdef HAVE_ARC4RANDOM
hash_set_raninit(arc4random());
#else
uint32_t v = getpid() ^ time(NULL);
srandom((unsigned long)v);
if(RAND_status() && RAND_bytes((unsigned char*)&v, sizeof(v)) > 0)
hash_set_raninit(v);
else hash_set_raninit(random());
#endif
rrl_mmap_init(nsd->child_count, nsd->options->rrl_size,
nsd->options->rrl_ratelimit,
nsd->options->rrl_whitelist_ratelimit,
nsd->options->rrl_slip,
nsd->options->rrl_ipv4_prefix_length,
nsd->options->rrl_ipv6_prefix_length);
#endif /* RATELIMIT */
/* Open the database... */
if ((nsd->db = namedb_open(nsd->dbfile, nsd->options)) == NULL) {
log_msg(LOG_ERR, "unable to open the database %s: %s",
nsd->dbfile, strerror(errno));
unlink(nsd->task[0]->fname);
unlink(nsd->task[1]->fname);
xfrd_del_tempdir(nsd);
return -1;
}
/* check if zone files have been modified */
/* NULL for taskudb because we send soainfo in a moment, batched up,
* for all zones */
if(nsd->options->zonefiles_check || (nsd->options->database == NULL ||
nsd->options->database[0] == 0))
namedb_check_zonefiles(nsd, nsd->options, NULL, NULL);
compression_table_capacity = 0;
initialize_dname_compression_tables(nsd);
#ifdef BIND8_STATS
/* Initialize times... */
time(&nsd->st.boot);
set_bind8_alarm(nsd);
#endif /* BIND8_STATS */
return 0;
}
/*
* Fork the required number of servers.
*/
static int
server_start_children(struct nsd *nsd, region_type* region, netio_type* netio,
int* xfrd_sock_p)
{
size_t i;
/* Start all child servers initially. */
for (i = 0; i < nsd->child_count; ++i) {
nsd->children[i].pid = 0;
}
return restart_child_servers(nsd, region, netio, xfrd_sock_p);
}
void
server_close_all_sockets(struct nsd_socket sockets[], size_t n)
{
size_t i;
/* Close all the sockets... */
for (i = 0; i < n; ++i) {
if (sockets[i].s != -1) {
close(sockets[i].s);
freeaddrinfo(sockets[i].addr);
sockets[i].s = -1;
}
}
}
/*
* Close the sockets, shutdown the server and exit.
* Does not return.
*
*/
void
server_shutdown(struct nsd *nsd)
{
size_t i;
server_close_all_sockets(nsd->udp, nsd->ifs);
server_close_all_sockets(nsd->tcp, nsd->ifs);
/* CHILD: close command channel to parent */
if(nsd->this_child && nsd->this_child->parent_fd != -1)
{
close(nsd->this_child->parent_fd);
nsd->this_child->parent_fd = -1;
}
/* SERVER: close command channels to children */
if(!nsd->this_child)
{
for(i=0; i < nsd->child_count; ++i)
if(nsd->children[i].child_fd != -1)
{
close(nsd->children[i].child_fd);
nsd->children[i].child_fd = -1;
}
}
tsig_finalize();
#ifdef HAVE_SSL
daemon_remote_delete(nsd->rc); /* ssl-delete secret keys */
#endif
#if 0 /* OS collects memory pages */
nsd_options_destroy(nsd->options);
region_destroy(nsd->region);
#endif
log_finalize();
exit(0);
}
void
server_prepare_xfrd(struct nsd* nsd)
{
char tmpfile[256];
/* create task mmaps */
nsd->mytask = 0;
snprintf(tmpfile, sizeof(tmpfile), "%snsd.%u.task.0",
nsd->options->xfrdir, (unsigned)getpid());
nsd->task[0] = task_file_create(tmpfile);
if(!nsd->task[0])
exit(1);
snprintf(tmpfile, sizeof(tmpfile), "%snsd.%u.task.1",
nsd->options->xfrdir, (unsigned)getpid());
nsd->task[1] = task_file_create(tmpfile);
if(!nsd->task[1]) {
unlink(nsd->task[0]->fname);
exit(1);
}
assert(udb_base_get_userdata(nsd->task[0])->data == 0);
assert(udb_base_get_userdata(nsd->task[1])->data == 0);
/* create xfrd listener structure */
nsd->xfrd_listener = region_alloc(nsd->region,
sizeof(netio_handler_type));
nsd->xfrd_listener->user_data = (struct ipc_handler_conn_data*)
region_alloc(nsd->region, sizeof(struct ipc_handler_conn_data));
nsd->xfrd_listener->fd = -1;
((struct ipc_handler_conn_data*)nsd->xfrd_listener->user_data)->nsd =
nsd;
((struct ipc_handler_conn_data*)nsd->xfrd_listener->user_data)->conn =
xfrd_tcp_create(nsd->region, QIOBUFSZ);
}
void
server_start_xfrd(struct nsd *nsd, int del_db, int reload_active)
{
pid_t pid;
int sockets[2] = {0,0};
struct ipc_handler_conn_data *data;
if(nsd->xfrd_listener->fd != -1)
close(nsd->xfrd_listener->fd);
if(del_db) {
/* recreate taskdb that xfrd was using, it may be corrupt */
/* we (or reload) use nsd->mytask, and xfrd uses the other */
char* tmpfile = nsd->task[1-nsd->mytask]->fname;
nsd->task[1-nsd->mytask]->fname = NULL;
/* free alloc already, so udb does not shrink itself */
udb_alloc_delete(nsd->task[1-nsd->mytask]->alloc);
nsd->task[1-nsd->mytask]->alloc = NULL;
udb_base_free(nsd->task[1-nsd->mytask]);
/* create new file, overwrite the old one */
nsd->task[1-nsd->mytask] = task_file_create(tmpfile);
free(tmpfile);
}
if (socketpair(AF_UNIX, SOCK_STREAM, 0, sockets) == -1) {
log_msg(LOG_ERR, "startxfrd failed on socketpair: %s", strerror(errno));
return;
}
pid = fork();
switch (pid) {
case -1:
log_msg(LOG_ERR, "fork xfrd failed: %s", strerror(errno));
break;
default:
/* PARENT: close first socket, use second one */
close(sockets[0]);
if (fcntl(sockets[1], F_SETFL, O_NONBLOCK) == -1) {
log_msg(LOG_ERR, "cannot fcntl pipe: %s", strerror(errno));
}
if(del_db) xfrd_free_namedb(nsd);
/* use other task than I am using, since if xfrd died and is
* restarted, the reload is using nsd->mytask */
nsd->mytask = 1 - nsd->mytask;
xfrd_init(sockets[1], nsd, del_db, reload_active, pid);
/* ENOTREACH */
break;
case 0:
/* CHILD: close second socket, use first one */
close(sockets[1]);
if (fcntl(sockets[0], F_SETFL, O_NONBLOCK) == -1) {
log_msg(LOG_ERR, "cannot fcntl pipe: %s", strerror(errno));
}
nsd->xfrd_listener->fd = sockets[0];
break;
}
/* server-parent only */
nsd->xfrd_listener->timeout = NULL;
nsd->xfrd_listener->event_types = NETIO_EVENT_READ;
nsd->xfrd_listener->event_handler = parent_handle_xfrd_command;
/* clear ongoing ipc reads */
data = (struct ipc_handler_conn_data *) nsd->xfrd_listener->user_data;
data->conn->is_reading = 0;
}
/** add all soainfo to taskdb */
static void
add_all_soa_to_task(struct nsd* nsd, struct udb_base* taskudb)
{
struct radnode* n;
udb_ptr task_last; /* last task, mytask is empty so NULL */
/* add all SOA INFO to mytask */
udb_ptr_init(&task_last, taskudb);
for(n=radix_first(nsd->db->zonetree); n; n=radix_next(n)) {
task_new_soainfo(taskudb, &task_last, (zone_type*)n->elem, 0);
}
udb_ptr_unlink(&task_last, taskudb);
}
void
server_send_soa_xfrd(struct nsd* nsd, int shortsoa)
{
/* normally this exchanges the SOA from nsd->xfrd and the expire back.
* parent fills one taskdb with soas, xfrd fills other with expires.
* then they exchange and process.
* shortsoa: xfrd crashes and needs to be restarted and one taskdb
* may be in use by reload. Fill SOA in taskdb and give to xfrd.
* expire notifications can be sent back via a normal reload later
* (xfrd will wait for current running reload to finish if any).
*/
sig_atomic_t cmd = 0;
pid_t mypid;
int xfrd_sock = nsd->xfrd_listener->fd;
struct udb_base* taskudb = nsd->task[nsd->mytask];
udb_ptr t;
if(!shortsoa) {
if(nsd->signal_hint_shutdown) {
shutdown:
log_msg(LOG_WARNING, "signal received, shutting down...");
server_close_all_sockets(nsd->udp, nsd->ifs);
server_close_all_sockets(nsd->tcp, nsd->ifs);
#ifdef HAVE_SSL
daemon_remote_close(nsd->rc);
#endif
/* Unlink it if possible... */
unlinkpid(nsd->pidfile);
unlink(nsd->task[0]->fname);
unlink(nsd->task[1]->fname);
/* write the nsd.db to disk, wait for it to complete */
udb_base_sync(nsd->db->udb, 1);
udb_base_close(nsd->db->udb);
server_shutdown(nsd);
exit(0);
}
}
if(shortsoa) {
/* put SOA in xfrd task because mytask may be in use */
taskudb = nsd->task[1-nsd->mytask];
}
add_all_soa_to_task(nsd, taskudb);
if(!shortsoa) {
/* wait for xfrd to signal task is ready, RELOAD signal */
if(block_read(nsd, xfrd_sock, &cmd, sizeof(cmd), -1) != sizeof(cmd) ||
cmd != NSD_RELOAD) {
log_msg(LOG_ERR, "did not get start signal from xfrd");
exit(1);
}
if(nsd->signal_hint_shutdown) {
goto shutdown;
}
}
/* give xfrd our task, signal it with RELOAD_DONE */
task_process_sync(taskudb);
cmd = NSD_RELOAD_DONE;
if(!write_socket(xfrd_sock, &cmd, sizeof(cmd))) {
log_msg(LOG_ERR, "problems sending soa end from reload %d to xfrd: %s",
(int)nsd->pid, strerror(errno));
}
mypid = getpid();
if(!write_socket(nsd->xfrd_listener->fd, &mypid, sizeof(mypid))) {
log_msg(LOG_ERR, "problems sending reloadpid to xfrd: %s",
strerror(errno));
}
if(!shortsoa) {
/* process the xfrd task works (expiry data) */
nsd->mytask = 1 - nsd->mytask;
taskudb = nsd->task[nsd->mytask];
task_remap(taskudb);
udb_ptr_new(&t, taskudb, udb_base_get_userdata(taskudb));
while(!udb_ptr_is_null(&t)) {
task_process_expire(nsd->db, TASKLIST(&t));
udb_ptr_set_rptr(&t, taskudb, &TASKLIST(&t)->next);
}
udb_ptr_unlink(&t, taskudb);
task_clear(taskudb);
/* tell xfrd that the task is emptied, signal with RELOAD_DONE */
cmd = NSD_RELOAD_DONE;
if(!write_socket(xfrd_sock, &cmd, sizeof(cmd))) {
log_msg(LOG_ERR, "problems sending soa end from reload %d to xfrd: %s",
(int)nsd->pid, strerror(errno));
}
}
}
/* pass timeout=-1 for blocking. Returns size, 0, -1(err), or -2(timeout) */
ssize_t
block_read(struct nsd* nsd, int s, void* p, ssize_t sz, int timeout)
{
uint8_t* buf = (uint8_t*) p;
ssize_t total = 0;
fd_set rfds;
struct timeval tv;
FD_ZERO(&rfds);
while( total < sz) {
ssize_t ret;
FD_SET(s, &rfds);
tv.tv_sec = timeout;
tv.tv_usec = 0;
ret = select(s+1, &rfds, NULL, NULL, timeout==-1?NULL:&tv);
if(ret == -1) {
if(errno == EAGAIN)
/* blocking read */
continue;
if(errno == EINTR) {
if(nsd && (nsd->signal_hint_quit || nsd->signal_hint_shutdown))
return -1;
/* other signals can be handled later */
continue;
}
/* some error */
return -1;
}
if(ret == 0) {
/* operation timed out */
return -2;
}
ret = read(s, buf+total, sz-total);
if(ret == -1) {
if(errno == EAGAIN)
/* blocking read */
continue;
if(errno == EINTR) {
if(nsd && (nsd->signal_hint_quit || nsd->signal_hint_shutdown))
return -1;
/* other signals can be handled later */
continue;
}
/* some error */
return -1;
}
if(ret == 0) {
/* closed connection! */
return 0;
}
total += ret;
}
return total;
}
static void
reload_process_tasks(struct nsd* nsd, udb_ptr* last_task, int cmdsocket)
{
sig_atomic_t cmd = NSD_QUIT_SYNC;
udb_ptr t, next;
udb_base* u = nsd->task[nsd->mytask];
udb_ptr_init(&next, u);
udb_ptr_new(&t, u, udb_base_get_userdata(u));
udb_base_set_userdata(u, 0);
while(!udb_ptr_is_null(&t)) {
/* store next in list so this one can be deleted or reused */
udb_ptr_set_rptr(&next, u, &TASKLIST(&t)->next);
udb_rptr_zero(&TASKLIST(&t)->next, u);
/* process task t */
/* append results for task t and update last_task */
task_process_in_reload(nsd, u, last_task, &t);
/* go to next */
udb_ptr_set_ptr(&t, u, &next);
/* if the parent has quit, we must quit too, poll the fd for cmds */
if(block_read(nsd, cmdsocket, &cmd, sizeof(cmd), 0) == sizeof(cmd)) {
DEBUG(DEBUG_IPC,1, (LOG_INFO, "reload: ipc command from main %d", (int)cmd));
if(cmd == NSD_QUIT) {
DEBUG(DEBUG_IPC,1, (LOG_INFO, "reload: quit to follow nsd"));
/* sync to disk (if needed) */
udb_base_sync(nsd->db->udb, 0);
/* unlink files of remainder of tasks */
while(!udb_ptr_is_null(&t)) {
if(TASKLIST(&t)->task_type == task_apply_xfr) {
xfrd_unlink_xfrfile(nsd, TASKLIST(&t)->yesno);
}
udb_ptr_set_rptr(&t, u, &TASKLIST(&t)->next);
}
udb_ptr_unlink(&t, u);
udb_ptr_unlink(&next, u);
exit(0);
}
}
}
udb_ptr_unlink(&t, u);
udb_ptr_unlink(&next, u);
}
#ifdef BIND8_STATS
static void
parent_send_stats(struct nsd* nsd, int cmdfd)
{
size_t i;
if(!write_socket(cmdfd, &nsd->st, sizeof(nsd->st))) {
log_msg(LOG_ERR, "could not write stats to reload");
return;
}
for(i=0; i<nsd->child_count; i++)
if(!write_socket(cmdfd, &nsd->children[i].query_count,
sizeof(stc_t))) {
log_msg(LOG_ERR, "could not write stats to reload");
return;
}
}
static void
reload_do_stats(int cmdfd, struct nsd* nsd, udb_ptr* last)
{
struct nsdst s;
stc_t* p;
size_t i;
if(block_read(nsd, cmdfd, &s, sizeof(s),
RELOAD_SYNC_TIMEOUT) != sizeof(s)) {
log_msg(LOG_ERR, "could not read stats from oldpar");
return;
}
s.db_disk = (nsd->db->udb?nsd->db->udb->base_size:0);
s.db_mem = region_get_mem(nsd->db->region);
p = (stc_t*)task_new_stat_info(nsd->task[nsd->mytask], last, &s,
nsd->child_count);
if(!p) return;
for(i=0; i<nsd->child_count; i++) {
if(block_read(nsd, cmdfd, p++, sizeof(stc_t), 1)!=sizeof(stc_t))
return;
}
}
#endif /* BIND8_STATS */
/*
* Reload the database, stop parent, re-fork children and continue.
* as server_main.
*/
static void
server_reload(struct nsd *nsd, region_type* server_region, netio_type* netio,
int cmdsocket)
{
pid_t mypid;
sig_atomic_t cmd = NSD_QUIT_SYNC;
int ret;
udb_ptr last_task;
struct sigaction old_sigchld, ign_sigchld;
/* ignore SIGCHLD from the previous server_main that used this pid */
memset(&ign_sigchld, 0, sizeof(ign_sigchld));
ign_sigchld.sa_handler = SIG_IGN;
sigaction(SIGCHLD, &ign_sigchld, &old_sigchld);
/* see what tasks we got from xfrd */
task_remap(nsd->task[nsd->mytask]);
udb_ptr_init(&last_task, nsd->task[nsd->mytask]);
udb_compact_inhibited(nsd->db->udb, 1);
reload_process_tasks(nsd, &last_task, cmdsocket);
udb_compact_inhibited(nsd->db->udb, 0);
udb_compact(nsd->db->udb);
#ifndef NDEBUG
if(nsd_debug_level >= 1)
region_log_stats(nsd->db->region);
#endif /* NDEBUG */
/* sync to disk (if needed) */
udb_base_sync(nsd->db->udb, 0);
initialize_dname_compression_tables(nsd);
#ifdef BIND8_STATS
/* Restart dumping stats if required. */
time(&nsd->st.boot);
set_bind8_alarm(nsd);
#endif
/* listen for the signals of failed children again */
sigaction(SIGCHLD, &old_sigchld, NULL);
/* Start new child processes */
if (server_start_children(nsd, server_region, netio, &nsd->
xfrd_listener->fd) != 0) {
send_children_quit(nsd);
exit(1);
}
/* if the parent has quit, we must quit too, poll the fd for cmds */
if(block_read(nsd, cmdsocket, &cmd, sizeof(cmd), 0) == sizeof(cmd)) {
DEBUG(DEBUG_IPC,1, (LOG_INFO, "reload: ipc command from main %d", (int)cmd));
if(cmd == NSD_QUIT) {
DEBUG(DEBUG_IPC,1, (LOG_INFO, "reload: quit to follow nsd"));
send_children_quit(nsd);
exit(0);
}
}
/* Send quit command to parent: blocking, wait for receipt. */
do {
DEBUG(DEBUG_IPC,1, (LOG_INFO, "reload: ipc send quit to main"));
if (!write_socket(cmdsocket, &cmd, sizeof(cmd)))
{
log_msg(LOG_ERR, "problems sending command from reload to oldnsd: %s",
strerror(errno));
}
/* blocking: wait for parent to really quit. (it sends RELOAD as ack) */
DEBUG(DEBUG_IPC,1, (LOG_INFO, "reload: ipc wait for ack main"));
ret = block_read(nsd, cmdsocket, &cmd, sizeof(cmd),
RELOAD_SYNC_TIMEOUT);
if(ret == -2) {
DEBUG(DEBUG_IPC, 1, (LOG_ERR, "reload timeout QUITSYNC. retry"));
}
} while (ret == -2);
if(ret == -1) {
log_msg(LOG_ERR, "reload: could not wait for parent to quit: %s",
strerror(errno));
}
DEBUG(DEBUG_IPC,1, (LOG_INFO, "reload: ipc reply main %d %d", ret, (int)cmd));
if(cmd == NSD_QUIT) {
/* small race condition possible here, parent got quit cmd. */
send_children_quit(nsd);
exit(1);
}
assert(ret==-1 || ret == 0 || cmd == NSD_RELOAD);
#ifdef BIND8_STATS
reload_do_stats(cmdsocket, nsd, &last_task);
#endif
udb_ptr_unlink(&last_task, nsd->task[nsd->mytask]);
task_process_sync(nsd->task[nsd->mytask]);
/* send soainfo to the xfrd process, signal it that reload is done,
* it picks up the taskudb */
cmd = NSD_RELOAD_DONE;
if(!write_socket(nsd->xfrd_listener->fd, &cmd, sizeof(cmd))) {
log_msg(LOG_ERR, "problems sending reload_done xfrd: %s",
strerror(errno));
}
mypid = getpid();
if(!write_socket(nsd->xfrd_listener->fd, &mypid, sizeof(mypid))) {
log_msg(LOG_ERR, "problems sending reloadpid to xfrd: %s",
strerror(errno));
}
/* try to reopen file */
if (nsd->file_rotation_ok)
log_reopen(nsd->log_filename, 1);
/* exit reload, continue as new server_main */
}
/*
* Get the mode depending on the signal hints that have been received.
* Multiple signal hints can be received and will be handled in turn.
*/
static sig_atomic_t
server_signal_mode(struct nsd *nsd)
{
if(nsd->signal_hint_quit) {
nsd->signal_hint_quit = 0;
return NSD_QUIT;
}
else if(nsd->signal_hint_shutdown) {
nsd->signal_hint_shutdown = 0;
return NSD_SHUTDOWN;
}
else if(nsd->signal_hint_child) {
nsd->signal_hint_child = 0;
return NSD_REAP_CHILDREN;
}
else if(nsd->signal_hint_reload) {
nsd->signal_hint_reload = 0;
return NSD_RELOAD;
}
else if(nsd->signal_hint_reload_hup) {
nsd->signal_hint_reload_hup = 0;
return NSD_RELOAD_REQ;
}
else if(nsd->signal_hint_stats) {
nsd->signal_hint_stats = 0;
#ifdef BIND8_STATS
set_bind8_alarm(nsd);
#endif
return NSD_STATS;
}
else if(nsd->signal_hint_statsusr) {
nsd->signal_hint_statsusr = 0;
return NSD_STATS;
}
return NSD_RUN;
}
/*
* The main server simply waits for signals and child processes to
* terminate. Child processes are restarted as necessary.
*/
void
server_main(struct nsd *nsd)
{
region_type *server_region = region_create(xalloc, free);
netio_type *netio = netio_create(server_region);
netio_handler_type reload_listener;
int reload_sockets[2] = {-1, -1};
struct timespec timeout_spec;
int status;
pid_t child_pid;
pid_t reload_pid = -1;
sig_atomic_t mode;
/* Ensure we are the main process */
assert(nsd->server_kind == NSD_SERVER_MAIN);
/* Add listener for the XFRD process */
netio_add_handler(netio, nsd->xfrd_listener);
/* Start the child processes that handle incoming queries */
if (server_start_children(nsd, server_region, netio,
&nsd->xfrd_listener->fd) != 0) {
send_children_quit(nsd);
exit(1);
}
reload_listener.fd = -1;
/* This_child MUST be 0, because this is the parent process */
assert(nsd->this_child == 0);
/* Run the server until we get a shutdown signal */
while ((mode = nsd->mode) != NSD_SHUTDOWN) {
/* Did we receive a signal that changes our mode? */
if(mode == NSD_RUN) {
nsd->mode = mode = server_signal_mode(nsd);
}
switch (mode) {
case NSD_RUN:
/* see if any child processes terminated */
while((child_pid = waitpid(-1, &status, WNOHANG)) != -1 && child_pid != 0) {
int is_child = delete_child_pid(nsd, child_pid);
if (is_child != -1 && nsd->children[is_child].need_to_exit) {
if(nsd->children[is_child].child_fd == -1)
nsd->children[is_child].has_exited = 1;
parent_check_all_children_exited(nsd);
} else if(is_child != -1) {
log_msg(LOG_WARNING,
"server %d died unexpectedly with status %d, restarting",
(int) child_pid, status);
restart_child_servers(nsd, server_region, netio,
&nsd->xfrd_listener->fd);
} else if (child_pid == reload_pid) {
sig_atomic_t cmd = NSD_RELOAD_DONE;
pid_t mypid;
log_msg(LOG_WARNING,
"Reload process %d failed with status %d, continuing with old database",
(int) child_pid, status);
reload_pid = -1;
if(reload_listener.fd != -1) close(reload_listener.fd);
reload_listener.fd = -1;
reload_listener.event_types = NETIO_EVENT_NONE;
task_process_sync(nsd->task[nsd->mytask]);
/* inform xfrd reload attempt ended */
if(!write_socket(nsd->xfrd_listener->fd,
&cmd, sizeof(cmd))) {
log_msg(LOG_ERR, "problems "
"sending SOAEND to xfrd: %s",
strerror(errno));
}
mypid = getpid();
if(!write_socket(nsd->xfrd_listener->fd, &mypid, sizeof(mypid))) {
log_msg(LOG_ERR, "problems sending reloadpid to xfrd: %s",
strerror(errno));
}
} else if(status != 0) {
/* check for status, because we get
* the old-servermain because reload
* is the process-parent of old-main,
* and we get older server-processes
* that are exiting after a reload */
log_msg(LOG_WARNING,
"process %d terminated with status %d",
(int) child_pid, status);
}
}
if (child_pid == -1) {
if (errno == EINTR) {
continue;
}
if (errno != ECHILD)
log_msg(LOG_WARNING, "wait failed: %s", strerror(errno));
}
if (nsd->mode != NSD_RUN)
break;
/* timeout to collect processes. In case no sigchild happens. */
timeout_spec.tv_sec = 60;
timeout_spec.tv_nsec = 0;
/* listen on ports, timeout for collecting terminated children */
if(netio_dispatch(netio, &timeout_spec, 0) == -1) {
if (errno != EINTR) {
log_msg(LOG_ERR, "netio_dispatch failed: %s", strerror(errno));
}
}
if(nsd->restart_children) {
restart_child_servers(nsd, server_region, netio,
&nsd->xfrd_listener->fd);
nsd->restart_children = 0;
}
if(nsd->reload_failed) {
sig_atomic_t cmd = NSD_RELOAD_DONE;
pid_t mypid;
nsd->reload_failed = 0;
log_msg(LOG_WARNING,
"Reload process %d failed, continuing with old database",
(int) reload_pid);
reload_pid = -1;
if(reload_listener.fd != -1) close(reload_listener.fd);
reload_listener.fd = -1;
reload_listener.event_types = NETIO_EVENT_NONE;
task_process_sync(nsd->task[nsd->mytask]);
/* inform xfrd reload attempt ended */
if(!write_socket(nsd->xfrd_listener->fd,
&cmd, sizeof(cmd))) {
log_msg(LOG_ERR, "problems "
"sending SOAEND to xfrd: %s",
strerror(errno));
}
mypid = getpid();
if(!write_socket(nsd->xfrd_listener->fd, &mypid, sizeof(mypid))) {
log_msg(LOG_ERR, "problems sending reloadpid to xfrd: %s",
strerror(errno));
}
}
break;
case NSD_RELOAD_REQ: {
sig_atomic_t cmd = NSD_RELOAD_REQ;
log_msg(LOG_WARNING, "SIGHUP received, reloading...");
DEBUG(DEBUG_IPC,1, (LOG_INFO,
"main: ipc send reload_req to xfrd"));
if(!write_socket(nsd->xfrd_listener->fd,
&cmd, sizeof(cmd))) {
log_msg(LOG_ERR, "server_main: could not send "
"reload_req to xfrd: %s", strerror(errno));
}
nsd->mode = NSD_RUN;
} break;
case NSD_RELOAD:
/* Continue to run nsd after reload */
nsd->mode = NSD_RUN;
DEBUG(DEBUG_IPC,1, (LOG_INFO, "reloading..."));
if (reload_pid != -1) {
log_msg(LOG_WARNING, "Reload already in progress (pid = %d)",
(int) reload_pid);
break;
}
/* switch the mytask to keep track of who owns task*/
nsd->mytask = 1 - nsd->mytask;
if (socketpair(AF_UNIX, SOCK_STREAM, 0, reload_sockets) == -1) {
log_msg(LOG_ERR, "reload failed on socketpair: %s", strerror(errno));
reload_pid = -1;
break;
}
/* Do actual reload */
reload_pid = fork();
switch (reload_pid) {
case -1:
log_msg(LOG_ERR, "fork failed: %s", strerror(errno));
break;
default:
/* PARENT */
close(reload_sockets[0]);
server_reload(nsd, server_region, netio,
reload_sockets[1]);
DEBUG(DEBUG_IPC,2, (LOG_INFO, "Reload exited to become new main"));
close(reload_sockets[1]);
DEBUG(DEBUG_IPC,2, (LOG_INFO, "Reload closed"));
/* drop stale xfrd ipc data */
((struct ipc_handler_conn_data*)nsd->
xfrd_listener->user_data)
->conn->is_reading = 0;
reload_pid = -1;
reload_listener.fd = -1;
reload_listener.event_types = NETIO_EVENT_NONE;
DEBUG(DEBUG_IPC,2, (LOG_INFO, "Reload resetup; run"));
break;
case 0:
/* CHILD */
/* server_main keep running until NSD_QUIT_SYNC
* received from reload. */
close(reload_sockets[1]);
reload_listener.fd = reload_sockets[0];
reload_listener.timeout = NULL;
reload_listener.user_data = nsd;
reload_listener.event_types = NETIO_EVENT_READ;
reload_listener.event_handler = parent_handle_reload_command; /* listens to Quit */
netio_add_handler(netio, &reload_listener);
reload_pid = getppid();
break;
}
break;
case NSD_QUIT_SYNC:
/* synchronisation of xfrd, parent and reload */
if(!nsd->quit_sync_done && reload_listener.fd != -1) {
sig_atomic_t cmd = NSD_RELOAD;
/* stop xfrd ipc writes in progress */
DEBUG(DEBUG_IPC,1, (LOG_INFO,
"main: ipc send indication reload"));
if(!write_socket(nsd->xfrd_listener->fd,
&cmd, sizeof(cmd))) {
log_msg(LOG_ERR, "server_main: could not send reload "
"indication to xfrd: %s", strerror(errno));
}
/* wait for ACK from xfrd */
DEBUG(DEBUG_IPC,1, (LOG_INFO, "main: wait ipc reply xfrd"));
nsd->quit_sync_done = 1;
}
nsd->mode = NSD_RUN;
break;
case NSD_QUIT:
/* silent shutdown during reload */
if(reload_listener.fd != -1) {
/* acknowledge the quit, to sync reload that we will really quit now */
sig_atomic_t cmd = NSD_RELOAD;
DEBUG(DEBUG_IPC,1, (LOG_INFO, "main: ipc ack reload"));
if(!write_socket(reload_listener.fd, &cmd, sizeof(cmd))) {
log_msg(LOG_ERR, "server_main: "
"could not ack quit: %s", strerror(errno));
}
#ifdef BIND8_STATS
parent_send_stats(nsd, reload_listener.fd);
#endif /* BIND8_STATS */
close(reload_listener.fd);
}
DEBUG(DEBUG_IPC,1, (LOG_INFO, "server_main: shutdown sequence"));
/* only quit children after xfrd has acked */
send_children_quit(nsd);
#if 0 /* OS collects memory pages */
region_destroy(server_region);
#endif
server_shutdown(nsd);
/* ENOTREACH */
break;
case NSD_SHUTDOWN:
break;
case NSD_REAP_CHILDREN:
/* continue; wait for child in run loop */
nsd->mode = NSD_RUN;
break;
case NSD_STATS:
#ifdef BIND8_STATS
set_children_stats(nsd);
#endif
nsd->mode = NSD_RUN;
break;
default:
log_msg(LOG_WARNING, "NSD main server mode invalid: %d", (int)nsd->mode);
nsd->mode = NSD_RUN;
break;
}
}
log_msg(LOG_WARNING, "signal received, shutting down...");
/* close opened ports to avoid race with restart of nsd */
server_close_all_sockets(nsd->udp, nsd->ifs);
server_close_all_sockets(nsd->tcp, nsd->ifs);
#ifdef HAVE_SSL
daemon_remote_close(nsd->rc);
#endif
send_children_quit_and_wait(nsd);
/* Unlink it if possible... */
unlinkpid(nsd->pidfile);
unlink(nsd->task[0]->fname);
unlink(nsd->task[1]->fname);
if(reload_listener.fd != -1) {
sig_atomic_t cmd = NSD_QUIT;
DEBUG(DEBUG_IPC,1, (LOG_INFO,
"main: ipc send quit to reload-process"));
if(!write_socket(reload_listener.fd, &cmd, sizeof(cmd))) {
log_msg(LOG_ERR, "server_main: could not send quit to reload: %s",
strerror(errno));
}
fsync(reload_listener.fd);
close(reload_listener.fd);
/* wait for reload to finish processing */
while(1) {
if(waitpid(reload_pid, NULL, 0) == -1) {
if(errno == EINTR) continue;
if(errno == ECHILD) break;
log_msg(LOG_ERR, "waitpid(reload %d): %s",
(int)reload_pid, strerror(errno));
}
break;
}
}
if(nsd->xfrd_listener->fd != -1) {
/* complete quit, stop xfrd */
sig_atomic_t cmd = NSD_QUIT;
DEBUG(DEBUG_IPC,1, (LOG_INFO,
"main: ipc send quit to xfrd"));
if(!write_socket(nsd->xfrd_listener->fd, &cmd, sizeof(cmd))) {
log_msg(LOG_ERR, "server_main: could not send quit to xfrd: %s",
strerror(errno));
}
fsync(nsd->xfrd_listener->fd);
close(nsd->xfrd_listener->fd);
(void)kill(nsd->pid, SIGTERM);
}
#if 0 /* OS collects memory pages */
region_destroy(server_region);
#endif
/* write the nsd.db to disk, wait for it to complete */
udb_base_sync(nsd->db->udb, 1);
udb_base_close(nsd->db->udb);
server_shutdown(nsd);
}
static query_state_type
server_process_query(struct nsd *nsd, struct query *query)
{
return query_process(query, nsd);
}
static query_state_type
server_process_query_udp(struct nsd *nsd, struct query *query)
{
#ifdef RATELIMIT
if(query_process(query, nsd) != QUERY_DISCARDED) {
if(rrl_process_query(query))
return rrl_slip(query);
else return QUERY_PROCESSED;
}
return QUERY_DISCARDED;
#else
return query_process(query, nsd);
#endif
}
struct event_base*
nsd_child_event_base(void)
{
struct event_base* base;
#ifdef USE_MINI_EVENT
static time_t secs;
static struct timeval now;
base = event_init(&secs, &now);
#else
# if defined(HAVE_EV_LOOP) || defined(HAVE_EV_DEFAULT_LOOP)
/* libev */
base = (struct event_base *)ev_default_loop(EVFLAG_AUTO);
# else
/* libevent */
# ifdef HAVE_EVENT_BASE_NEW
base = event_base_new();
# else
base = event_init();
# endif
# endif
#endif
return base;
}
/*
* Serve DNS requests.
*/
void
server_child(struct nsd *nsd)
{
size_t i;
region_type *server_region = region_create(xalloc, free);
struct event_base* event_base = nsd_child_event_base();
query_type *udp_query;
sig_atomic_t mode;
if(!event_base) {
log_msg(LOG_ERR, "nsd server could not create event base");
exit(1);
}
#ifdef RATELIMIT
rrl_init((nsd->this_child - nsd->children)/sizeof(nsd->children[0]));
#endif
assert(nsd->server_kind != NSD_SERVER_MAIN);
DEBUG(DEBUG_IPC, 2, (LOG_INFO, "child process started"));
if (!(nsd->server_kind & NSD_SERVER_TCP)) {
server_close_all_sockets(nsd->tcp, nsd->ifs);
}
if (!(nsd->server_kind & NSD_SERVER_UDP)) {
server_close_all_sockets(nsd->udp, nsd->ifs);
}
if (nsd->this_child && nsd->this_child->parent_fd != -1) {
struct event *handler;
struct ipc_handler_conn_data* user_data =
(struct ipc_handler_conn_data*)region_alloc(
server_region, sizeof(struct ipc_handler_conn_data));
user_data->nsd = nsd;
user_data->conn = xfrd_tcp_create(server_region, QIOBUFSZ);
handler = (struct event*) region_alloc(
server_region, sizeof(*handler));
event_set(handler, nsd->this_child->parent_fd, EV_PERSIST|
EV_READ, child_handle_parent_command, user_data);
if(event_base_set(event_base, handler) != 0)
log_msg(LOG_ERR, "nsd ipcchild: event_base_set failed");
if(event_add(handler, NULL) != 0)
log_msg(LOG_ERR, "nsd ipcchild: event_add failed");
}
if (nsd->server_kind & NSD_SERVER_UDP) {
#if (defined(NONBLOCKING_IS_BROKEN) || !defined(HAVE_RECVMMSG))
udp_query = query_create(server_region,
compressed_dname_offsets, compression_table_size);
#else
udp_query = NULL;
memset(msgs, 0, sizeof(msgs));
for (i = 0; i < NUM_RECV_PER_SELECT; i++) {
queries[i] = query_create(server_region,
compressed_dname_offsets, compression_table_size);
query_reset(queries[i], UDP_MAX_MESSAGE_LEN, 0);
iovecs[i].iov_base = buffer_begin(queries[i]->packet);
iovecs[i].iov_len = buffer_remaining(queries[i]->packet);;
msgs[i].msg_hdr.msg_iov = &iovecs[i];
msgs[i].msg_hdr.msg_iovlen = 1;
msgs[i].msg_hdr.msg_name = &queries[i]->addr;
msgs[i].msg_hdr.msg_namelen = queries[i]->addrlen;
}
#endif
for (i = 0; i < nsd->ifs; ++i) {
struct udp_handler_data *data;
struct event *handler;
data = (struct udp_handler_data *) region_alloc(
server_region,
sizeof(struct udp_handler_data));
data->query = udp_query;
data->nsd = nsd;
data->socket = &nsd->udp[i];
handler = (struct event*) region_alloc(
server_region, sizeof(*handler));
event_set(handler, nsd->udp[i].s, EV_PERSIST|EV_READ,
handle_udp, data);
if(event_base_set(event_base, handler) != 0)
log_msg(LOG_ERR, "nsd udp: event_base_set failed");
if(event_add(handler, NULL) != 0)
log_msg(LOG_ERR, "nsd udp: event_add failed");
}
}
/*
* Keep track of all the TCP accept handlers so we can enable
* and disable them based on the current number of active TCP
* connections.
*/
tcp_accept_handler_count = nsd->ifs;
tcp_accept_handlers = (struct tcp_accept_handler_data*) region_alloc(
server_region, nsd->ifs * sizeof(*tcp_accept_handlers));
if (nsd->server_kind & NSD_SERVER_TCP) {
for (i = 0; i < nsd->ifs; ++i) {
struct event *handler = &tcp_accept_handlers[i].event;
struct tcp_accept_handler_data* data =
&tcp_accept_handlers[i];
data->nsd = nsd;
data->socket = &nsd->tcp[i];
event_set(handler, nsd->tcp[i].s, EV_PERSIST|EV_READ,
handle_tcp_accept, data);
if(event_base_set(event_base, handler) != 0)
log_msg(LOG_ERR, "nsd tcp: event_base_set failed");
if(event_add(handler, NULL) != 0)
log_msg(LOG_ERR, "nsd tcp: event_add failed");
data->event_added = 1;
}
} else tcp_accept_handler_count = 0;
/* The main loop... */
while ((mode = nsd->mode) != NSD_QUIT) {
if(mode == NSD_RUN) nsd->mode = mode = server_signal_mode(nsd);
/* Do we need to do the statistics... */
if (mode == NSD_STATS) {
#ifdef BIND8_STATS
int p = nsd->st.period;
nsd->st.period = 1; /* force stats printout */
/* Dump the statistics */
bind8_stats(nsd);
nsd->st.period = p;
#else /* !BIND8_STATS */
log_msg(LOG_NOTICE, "Statistics support not enabled at compile time.");
#endif /* BIND8_STATS */
nsd->mode = NSD_RUN;
}
else if (mode == NSD_REAP_CHILDREN) {
/* got signal, notify parent. parent reaps terminated children. */
if (nsd->this_child->parent_fd != -1) {
sig_atomic_t parent_notify = NSD_REAP_CHILDREN;
if (write(nsd->this_child->parent_fd,
&parent_notify,
sizeof(parent_notify)) == -1)
{
log_msg(LOG_ERR, "problems sending command from %d to parent: %s",
(int) nsd->this_child->pid, strerror(errno));
}
} else /* no parent, so reap 'em */
while (waitpid(-1, NULL, WNOHANG) > 0) ;
nsd->mode = NSD_RUN;
}
else if(mode == NSD_RUN) {
/* Wait for a query... */
if(event_base_loop(event_base, EVLOOP_ONCE) == -1) {
if (errno != EINTR) {
log_msg(LOG_ERR, "dispatch failed: %s", strerror(errno));
break;
}
}
} else if(mode == NSD_QUIT) {
/* ignore here, quit */
} else {
log_msg(LOG_ERR, "mode bad value %d, back to service.",
(int)mode);
nsd->mode = NSD_RUN;
}
}
#ifdef BIND8_STATS
bind8_stats(nsd);
#endif /* BIND8_STATS */
#if 0 /* OS collects memory pages */
event_base_free(event_base);
region_destroy(server_region);
#endif
server_shutdown(nsd);
}
#if defined(HAVE_SENDMMSG) && !defined(NONBLOCKING_IS_BROKEN) && defined(HAVE_RECVMMSG)
static void
handle_udp(int fd, short event, void* arg)
{
struct udp_handler_data *data = (struct udp_handler_data *) arg;
int received, sent, recvcount, i;
struct query *q;
if (!(event & EV_READ)) {
return;
}
recvcount = recvmmsg(fd, msgs, NUM_RECV_PER_SELECT, 0, NULL);
/* this printf strangely gave a performance increase on Linux */
/* printf("recvcount %d \n", recvcount); */
if (recvcount == -1) {
if (errno != EAGAIN && errno != EINTR) {
log_msg(LOG_ERR, "recvmmsg failed: %s", strerror(errno));
STATUP(data->nsd, rxerr);
}
/* Simply no data available */
return;
}
for (i = 0; i < recvcount; i++) {
loopstart:
received = msgs[i].msg_len;
q = queries[i];
if (received == -1) {
log_msg(LOG_ERR, "recvmmsg %d failed %s", i, strerror(
msgs[i].msg_hdr.msg_flags));
STATUP(data->nsd, rxerr);
query_reset(queries[i], UDP_MAX_MESSAGE_LEN, 0);
iovecs[i].iov_len = buffer_remaining(q->packet);
goto swap_drop;
}
/* Account... */
if (data->socket->addr->ai_family == AF_INET) {
STATUP(data->nsd, qudp);
} else if (data->socket->addr->ai_family == AF_INET6) {
STATUP(data->nsd, qudp6);
}
buffer_skip(q->packet, received);
buffer_flip(q->packet);
/* Process and answer the query... */
if (server_process_query_udp(data->nsd, q) != QUERY_DISCARDED) {
if (RCODE(q->packet) == RCODE_OK && !AA(q->packet)) {
STATUP(data->nsd, nona);
}
/* Add EDNS0 and TSIG info if necessary. */
query_add_optional(q, data->nsd);
buffer_flip(q->packet);
iovecs[i].iov_len = buffer_remaining(q->packet);
#ifdef BIND8_STATS
/* Account the rcode & TC... */
STATUP2(data->nsd, rcode, RCODE(q->packet));
if (TC(q->packet))
STATUP(data->nsd, truncated);
#endif /* BIND8_STATS */
} else {
query_reset(queries[i], UDP_MAX_MESSAGE_LEN, 0);
iovecs[i].iov_len = buffer_remaining(q->packet);
swap_drop:
STATUP(data->nsd, dropped);
if(i != recvcount-1) {
/* swap with last and decrease recvcount */
struct mmsghdr mtmp = msgs[i];
struct iovec iotmp = iovecs[i];
recvcount--;
msgs[i] = msgs[recvcount];
iovecs[i] = iovecs[recvcount];
queries[i] = queries[recvcount];
msgs[recvcount] = mtmp;
iovecs[recvcount] = iotmp;
queries[recvcount] = q;
msgs[i].msg_hdr.msg_iov = &iovecs[i];
msgs[recvcount].msg_hdr.msg_iov = &iovecs[recvcount];
goto loopstart;
} else { recvcount --; }
}
}
/* send until all are sent */
i = 0;
while(i<recvcount) {
sent = sendmmsg(fd, &msgs[i], recvcount-i, 0);
if(sent == -1) {
const char* es = strerror(errno);
char a[48];
addr2str(&queries[i]->addr, a, sizeof(a));
log_msg(LOG_ERR, "sendmmsg [0]=%s count=%d failed: %s", a, (int)(recvcount-i), es);
#ifdef BIND8_STATS
data->nsd->st.txerr += recvcount-i;
#endif /* BIND8_STATS */
break;
}
i += sent;
}
for(i=0; i<recvcount; i++) {
query_reset(queries[i], UDP_MAX_MESSAGE_LEN, 0);
iovecs[i].iov_len = buffer_remaining(queries[i]->packet);
}
}
#else /* defined(HAVE_SENDMMSG) && !defined(NONBLOCKING_IS_BROKEN) && defined(HAVE_RECVMMSG) */
static void
handle_udp(int fd, short event, void* arg)
{
struct udp_handler_data *data = (struct udp_handler_data *) arg;
int received, sent;
#ifndef NONBLOCKING_IS_BROKEN
#ifdef HAVE_RECVMMSG
int recvcount;
#endif /* HAVE_RECVMMSG */
int i;
#endif /* NONBLOCKING_IS_BROKEN */
struct query *q;
#if (defined(NONBLOCKING_IS_BROKEN) || !defined(HAVE_RECVMMSG))
q = data->query;
#endif
if (!(event & EV_READ)) {
return;
}
#ifndef NONBLOCKING_IS_BROKEN
#ifdef HAVE_RECVMMSG
recvcount = recvmmsg(fd, msgs, NUM_RECV_PER_SELECT, 0, NULL);
/* this printf strangely gave a performance increase on Linux */
/* printf("recvcount %d \n", recvcount); */
if (recvcount == -1) {
if (errno != EAGAIN && errno != EINTR) {
log_msg(LOG_ERR, "recvmmsg failed: %s", strerror(errno));
STATUP(data->nsd, rxerr);
}
/* Simply no data available */
return;
}
for (i = 0; i < recvcount; i++) {
received = msgs[i].msg_len;
msgs[i].msg_hdr.msg_namelen = queries[i]->addrlen;
if (received == -1) {
log_msg(LOG_ERR, "recvmmsg failed");
STATUP(data->nsd, rxerr);
/* the error can be found in msgs[i].msg_hdr.msg_flags */
query_reset(queries[i], UDP_MAX_MESSAGE_LEN, 0);
continue;
}
q = queries[i];
#else
for(i=0; i<NUM_RECV_PER_SELECT; i++) {
#endif /* HAVE_RECVMMSG */
#endif /* NONBLOCKING_IS_BROKEN */
#if (defined(NONBLOCKING_IS_BROKEN) || !defined(HAVE_RECVMMSG))
/* Initialize the query... */
query_reset(q, UDP_MAX_MESSAGE_LEN, 0);
received = recvfrom(fd,
buffer_begin(q->packet),
buffer_remaining(q->packet),
0,
(struct sockaddr *)&q->addr,
&q->addrlen);
if (received == -1) {
if (errno != EAGAIN && errno != EINTR) {
log_msg(LOG_ERR, "recvfrom failed: %s", strerror(errno));
STATUP(data->nsd, rxerr);
}
return;
}
#endif /* NONBLOCKING_IS_BROKEN || !HAVE_RECVMMSG */
/* Account... */
if (data->socket->addr->ai_family == AF_INET) {
STATUP(data->nsd, qudp);
} else if (data->socket->addr->ai_family == AF_INET6) {
STATUP(data->nsd, qudp6);
}
buffer_skip(q->packet, received);
buffer_flip(q->packet);
/* Process and answer the query... */
if (server_process_query_udp(data->nsd, q) != QUERY_DISCARDED) {
if (RCODE(q->packet) == RCODE_OK && !AA(q->packet)) {
STATUP(data->nsd, nona);
}
/* Add EDNS0 and TSIG info if necessary. */
query_add_optional(q, data->nsd);
buffer_flip(q->packet);
sent = sendto(fd,
buffer_begin(q->packet),
buffer_remaining(q->packet),
0,
(struct sockaddr *) &q->addr,
q->addrlen);
if (sent == -1) {
const char* es = strerror(errno);
char a[48];
addr2str(&q->addr, a, sizeof(a));
log_msg(LOG_ERR, "sendto %s failed: %s", a, es);
STATUP(data->nsd, txerr);
} else if ((size_t) sent != buffer_remaining(q->packet)) {
log_msg(LOG_ERR, "sent %d in place of %d bytes", sent, (int) buffer_remaining(q->packet));
} else {
#ifdef BIND8_STATS
/* Account the rcode & TC... */
STATUP2(data->nsd, rcode, RCODE(q->packet));
if (TC(q->packet))
STATUP(data->nsd, truncated);
#endif /* BIND8_STATS */
}
} else {
STATUP(data->nsd, dropped);
}
#ifndef NONBLOCKING_IS_BROKEN
#ifdef HAVE_RECVMMSG
query_reset(queries[i], UDP_MAX_MESSAGE_LEN, 0);
#endif
}
#endif
}
#endif /* defined(HAVE_SENDMMSG) && !defined(NONBLOCKING_IS_BROKEN) && defined(HAVE_RECVMMSG) */
static void
cleanup_tcp_handler(struct tcp_handler_data* data)
{
event_del(&data->event);
close(data->event.ev_fd);
/*
* Enable the TCP accept handlers when the current number of
* TCP connections is about to drop below the maximum number
* of TCP connections.
*/
if (slowaccept || data->nsd->current_tcp_count == data->nsd->maximum_tcp_count) {
configure_handler_event_types(EV_READ|EV_PERSIST);
slowaccept = 0;
}
--data->nsd->current_tcp_count;
assert(data->nsd->current_tcp_count >= 0);
region_destroy(data->region);
}
static void
handle_tcp_reading(int fd, short event, void* arg)
{
struct tcp_handler_data *data = (struct tcp_handler_data *) arg;
ssize_t received;
struct event_base* ev_base;
struct timeval timeout;
if ((event & EV_TIMEOUT)) {
/* Connection timed out. */
cleanup_tcp_handler(data);
return;
}
if (data->nsd->tcp_query_count > 0 &&
data->query_count >= data->nsd->tcp_query_count) {
/* No more queries allowed on this tcp connection. */
cleanup_tcp_handler(data);
return;
}
assert((event & EV_READ));
if (data->bytes_transmitted == 0) {
query_reset(data->query, TCP_MAX_MESSAGE_LEN, 1);
}
/*
* Check if we received the leading packet length bytes yet.
*/
if (data->bytes_transmitted < sizeof(uint16_t)) {
received = read(fd,
(char *) &data->query->tcplen
+ data->bytes_transmitted,
sizeof(uint16_t) - data->bytes_transmitted);
if (received == -1) {
if (errno == EAGAIN || errno == EINTR) {
/*
* Read would block, wait until more
* data is available.
*/
return;
} else {
char buf[48];
addr2str(&data->query->addr, buf, sizeof(buf));
#ifdef ECONNRESET
if (verbosity >= 2 || errno != ECONNRESET)
#endif /* ECONNRESET */
log_msg(LOG_ERR, "failed reading from %s tcp: %s", buf, strerror(errno));
cleanup_tcp_handler(data);
return;
}
} else if (received == 0) {
/* EOF */
cleanup_tcp_handler(data);
return;
}
data->bytes_transmitted += received;
if (data->bytes_transmitted < sizeof(uint16_t)) {
/*
* Not done with the tcplen yet, wait for more
* data to become available.
*/
return;
}
assert(data->bytes_transmitted == sizeof(uint16_t));
data->query->tcplen = ntohs(data->query->tcplen);
/*
* Minimum query size is:
*
* Size of the header (12)
* + Root domain name (1)
* + Query class (2)
* + Query type (2)
*/
if (data->query->tcplen < QHEADERSZ + 1 + sizeof(uint16_t) + sizeof(uint16_t)) {
VERBOSITY(2, (LOG_WARNING, "packet too small, dropping tcp connection"));
cleanup_tcp_handler(data);
return;
}
if (data->query->tcplen > data->query->maxlen) {
VERBOSITY(2, (LOG_WARNING, "insufficient tcp buffer, dropping connection"));
cleanup_tcp_handler(data);
return;
}
buffer_set_limit(data->query->packet, data->query->tcplen);
}
assert(buffer_remaining(data->query->packet) > 0);
/* Read the (remaining) query data. */
received = read(fd,
buffer_current(data->query->packet),
buffer_remaining(data->query->packet));
if (received == -1) {
if (errno == EAGAIN || errno == EINTR) {
/*
* Read would block, wait until more data is
* available.
*/
return;
} else {
char buf[48];
addr2str(&data->query->addr, buf, sizeof(buf));
#ifdef ECONNRESET
if (verbosity >= 2 || errno != ECONNRESET)
#endif /* ECONNRESET */
log_msg(LOG_ERR, "failed reading from %s tcp: %s", buf, strerror(errno));
cleanup_tcp_handler(data);
return;
}
} else if (received == 0) {
/* EOF */
cleanup_tcp_handler(data);
return;
}
data->bytes_transmitted += received;
buffer_skip(data->query->packet, received);
if (buffer_remaining(data->query->packet) > 0) {
/*
* Message not yet complete, wait for more data to
* become available.
*/
return;
}
assert(buffer_position(data->query->packet) == data->query->tcplen);
/* Account... */
#ifndef INET6
STATUP(data->nsd, ctcp);
#else
if (data->query->addr.ss_family == AF_INET) {
STATUP(data->nsd, ctcp);
} else if (data->query->addr.ss_family == AF_INET6) {
STATUP(data->nsd, ctcp6);
}
#endif
/* We have a complete query, process it. */
/* tcp-query-count: handle query counter ++ */
data->query_count++;
buffer_flip(data->query->packet);
data->query_state = server_process_query(data->nsd, data->query);
if (data->query_state == QUERY_DISCARDED) {
/* Drop the packet and the entire connection... */
STATUP(data->nsd, dropped);
cleanup_tcp_handler(data);
return;
}
if (RCODE(data->query->packet) == RCODE_OK
&& !AA(data->query->packet))
{
STATUP(data->nsd, nona);
}
query_add_optional(data->query, data->nsd);
/* Switch to the tcp write handler. */
buffer_flip(data->query->packet);
data->query->tcplen = buffer_remaining(data->query->packet);
data->bytes_transmitted = 0;
timeout.tv_sec = data->nsd->tcp_timeout;
timeout.tv_usec = 0L;
ev_base = data->event.ev_base;
event_del(&data->event);
event_set(&data->event, fd, EV_PERSIST | EV_WRITE | EV_TIMEOUT,
handle_tcp_writing, data);
if(event_base_set(ev_base, &data->event) != 0)
log_msg(LOG_ERR, "event base set tcpr failed");
if(event_add(&data->event, &timeout) != 0)
log_msg(LOG_ERR, "event add tcpr failed");
/* see if we can write the answer right away(usually so,EAGAIN ifnot)*/
handle_tcp_writing(fd, EV_WRITE, data);
}
static void
handle_tcp_writing(int fd, short event, void* arg)
{
struct tcp_handler_data *data = (struct tcp_handler_data *) arg;
ssize_t sent;
struct query *q = data->query;
struct timeval timeout;
struct event_base* ev_base;
if ((event & EV_TIMEOUT)) {
/* Connection timed out. */
cleanup_tcp_handler(data);
return;
}
assert((event & EV_WRITE));
if (data->bytes_transmitted < sizeof(q->tcplen)) {
/* Writing the response packet length. */
uint16_t n_tcplen = htons(q->tcplen);
#ifdef HAVE_WRITEV
struct iovec iov[2];
iov[0].iov_base = (uint8_t*)&n_tcplen + data->bytes_transmitted;
iov[0].iov_len = sizeof(n_tcplen) - data->bytes_transmitted;
iov[1].iov_base = buffer_begin(q->packet);
iov[1].iov_len = buffer_limit(q->packet);
sent = writev(fd, iov, 2);
#else /* HAVE_WRITEV */
sent = write(fd,
(const char *) &n_tcplen + data->bytes_transmitted,
sizeof(n_tcplen) - data->bytes_transmitted);
#endif /* HAVE_WRITEV */
if (sent == -1) {
if (errno == EAGAIN || errno == EINTR) {
/*
* Write would block, wait until
* socket becomes writable again.
*/
return;
} else {
#ifdef ECONNRESET
if(verbosity >= 2 || errno != ECONNRESET)
#endif /* ECONNRESET */
#ifdef EPIPE
if(verbosity >= 2 || errno != EPIPE)
#endif /* EPIPE 'broken pipe' */
log_msg(LOG_ERR, "failed writing to tcp: %s", strerror(errno));
cleanup_tcp_handler(data);
return;
}
}
data->bytes_transmitted += sent;
if (data->bytes_transmitted < sizeof(q->tcplen)) {
/*
* Writing not complete, wait until socket
* becomes writable again.
*/
return;
}
#ifdef HAVE_WRITEV
sent -= sizeof(n_tcplen);
/* handle potential 'packet done' code */
goto packet_could_be_done;
#endif
}
sent = write(fd,
buffer_current(q->packet),
buffer_remaining(q->packet));
if (sent == -1) {
if (errno == EAGAIN || errno == EINTR) {
/*
* Write would block, wait until
* socket becomes writable again.
*/
return;
} else {
#ifdef ECONNRESET
if(verbosity >= 2 || errno != ECONNRESET)
#endif /* ECONNRESET */
#ifdef EPIPE
if(verbosity >= 2 || errno != EPIPE)
#endif /* EPIPE 'broken pipe' */
log_msg(LOG_ERR, "failed writing to tcp: %s", strerror(errno));
cleanup_tcp_handler(data);
return;
}
}
data->bytes_transmitted += sent;
#ifdef HAVE_WRITEV
packet_could_be_done:
#endif
buffer_skip(q->packet, sent);
if (data->bytes_transmitted < q->tcplen + sizeof(q->tcplen)) {
/*
* Still more data to write when socket becomes
* writable again.
*/
return;
}
assert(data->bytes_transmitted == q->tcplen + sizeof(q->tcplen));
if (data->query_state == QUERY_IN_AXFR) {
/* Continue processing AXFR and writing back results. */
buffer_clear(q->packet);
data->query_state = query_axfr(data->nsd, q);
if (data->query_state != QUERY_PROCESSED) {
query_add_optional(data->query, data->nsd);
/* Reset data. */
buffer_flip(q->packet);
q->tcplen = buffer_remaining(q->packet);
data->bytes_transmitted = 0;
/* Reset timeout. */
timeout.tv_sec = data->nsd->tcp_timeout;
timeout.tv_usec = 0L;
ev_base = data->event.ev_base;
event_del(&data->event);
event_set(&data->event, fd, EV_PERSIST | EV_WRITE | EV_TIMEOUT,
handle_tcp_writing, data);
if(event_base_set(ev_base, &data->event) != 0)
log_msg(LOG_ERR, "event base set tcpw failed");
if(event_add(&data->event, &timeout) != 0)
log_msg(LOG_ERR, "event add tcpw failed");
/*
* Write data if/when the socket is writable
* again.
*/
return;
}
}
/*
* Done sending, wait for the next request to arrive on the
* TCP socket by installing the TCP read handler.
*/
if (data->nsd->tcp_query_count > 0 &&
data->query_count >= data->nsd->tcp_query_count) {
(void) shutdown(fd, SHUT_WR);
}
data->bytes_transmitted = 0;
timeout.tv_sec = data->nsd->tcp_timeout;
timeout.tv_usec = 0L;
ev_base = data->event.ev_base;
event_del(&data->event);
event_set(&data->event, fd, EV_PERSIST | EV_READ | EV_TIMEOUT,
handle_tcp_reading, data);
if(event_base_set(ev_base, &data->event) != 0)
log_msg(LOG_ERR, "event base set tcpw failed");
if(event_add(&data->event, &timeout) != 0)
log_msg(LOG_ERR, "event add tcpw failed");
}
static void
handle_slowaccept_timeout(int ATTR_UNUSED(fd), short ATTR_UNUSED(event),
void* ATTR_UNUSED(arg))
{
if(slowaccept) {
configure_handler_event_types(EV_PERSIST | EV_READ);
slowaccept = 0;
}
}
/*
* Handle an incoming TCP connection. The connection is accepted and
* a new TCP reader event handler is added. The TCP handler
* is responsible for cleanup when the connection is closed.
*/
static void
handle_tcp_accept(int fd, short event, void* arg)
{
struct tcp_accept_handler_data *data
= (struct tcp_accept_handler_data *) arg;
int s;
struct tcp_handler_data *tcp_data;
region_type *tcp_region;
#ifdef INET6
struct sockaddr_storage addr;
#else
struct sockaddr_in addr;
#endif
socklen_t addrlen;
struct timeval timeout;
if (!(event & EV_READ)) {
return;
}
if (data->nsd->current_tcp_count >= data->nsd->maximum_tcp_count) {
return;
}
/* Accept it... */
addrlen = sizeof(addr);
s = accept(fd, (struct sockaddr *) &addr, &addrlen);
if (s == -1) {
/**
* EMFILE and ENFILE is a signal that the limit of open
* file descriptors has been reached. Pause accept().
* EINTR is a signal interrupt. The others are various OS ways
* of saying that the client has closed the connection.
*/
if (errno == EMFILE || errno == ENFILE) {
if (!slowaccept) {
/* disable accept events */
struct timeval tv;
configure_handler_event_types(0);
tv.tv_sec = SLOW_ACCEPT_TIMEOUT;
tv.tv_usec = 0L;
event_set(&slowaccept_event, -1, EV_TIMEOUT,
handle_slowaccept_timeout, NULL);
(void)event_base_set(data->event.ev_base,
&slowaccept_event);
(void)event_add(&slowaccept_event, &tv);
slowaccept = 1;
/* We don't want to spam the logs here */
}
} else if (errno != EINTR
&& errno != EWOULDBLOCK
#ifdef ECONNABORTED
&& errno != ECONNABORTED
#endif /* ECONNABORTED */
#ifdef EPROTO
&& errno != EPROTO
#endif /* EPROTO */
) {
log_msg(LOG_ERR, "accept failed: %s", strerror(errno));
}
return;
}
if (fcntl(s, F_SETFL, O_NONBLOCK) == -1) {
log_msg(LOG_ERR, "fcntl failed: %s", strerror(errno));
close(s);
return;
}
/*
* This region is deallocated when the TCP connection is
* closed by the TCP handler.
*/
tcp_region = region_create(xalloc, free);
tcp_data = (struct tcp_handler_data *) region_alloc(
tcp_region, sizeof(struct tcp_handler_data));
tcp_data->region = tcp_region;
tcp_data->query = query_create(tcp_region, compressed_dname_offsets,
compression_table_size);
tcp_data->nsd = data->nsd;
tcp_data->query_count = 0;
tcp_data->query_state = QUERY_PROCESSED;
tcp_data->bytes_transmitted = 0;
memcpy(&tcp_data->query->addr, &addr, addrlen);
tcp_data->query->addrlen = addrlen;
timeout.tv_sec = data->nsd->tcp_timeout;
timeout.tv_usec = 0;
event_set(&tcp_data->event, s, EV_PERSIST | EV_READ | EV_TIMEOUT,
handle_tcp_reading, tcp_data);
if(event_base_set(data->event.ev_base, &tcp_data->event) != 0)
log_msg(LOG_ERR, "cannot set tcp event base");
if(event_add(&tcp_data->event, &timeout) != 0)
log_msg(LOG_ERR, "cannot set tcp event base");
/*
* Keep track of the total number of TCP handlers installed so
* we can stop accepting connections when the maximum number
* of simultaneous TCP connections is reached.
*/
++data->nsd->current_tcp_count;
if (data->nsd->current_tcp_count == data->nsd->maximum_tcp_count) {
configure_handler_event_types(0);
}
}
static void
send_children_command(struct nsd* nsd, sig_atomic_t command, int timeout)
{
size_t i;
assert(nsd->server_kind == NSD_SERVER_MAIN && nsd->this_child == 0);
for (i = 0; i < nsd->child_count; ++i) {
if (nsd->children[i].pid > 0 && nsd->children[i].child_fd != -1) {
if (write(nsd->children[i].child_fd,
&command,
sizeof(command)) == -1)
{
if(errno != EAGAIN && errno != EINTR)
log_msg(LOG_ERR, "problems sending command %d to server %d: %s",
(int) command,
(int) nsd->children[i].pid,
strerror(errno));
} else if (timeout > 0) {
(void)block_read(NULL,
nsd->children[i].child_fd,
&command, sizeof(command), timeout);
}
fsync(nsd->children[i].child_fd);
close(nsd->children[i].child_fd);
nsd->children[i].child_fd = -1;
}
}
}
static void
send_children_quit(struct nsd* nsd)
{
DEBUG(DEBUG_IPC, 1, (LOG_INFO, "send children quit"));
send_children_command(nsd, NSD_QUIT, 0);
}
static void
send_children_quit_and_wait(struct nsd* nsd)
{
DEBUG(DEBUG_IPC, 1, (LOG_INFO, "send children quit and wait"));
send_children_command(nsd, NSD_QUIT_CHILD, 3);
}
#ifdef BIND8_STATS
static void
set_children_stats(struct nsd* nsd)
{
size_t i;
assert(nsd->server_kind == NSD_SERVER_MAIN && nsd->this_child == 0);
DEBUG(DEBUG_IPC, 1, (LOG_INFO, "parent set stats to send to children"));
for (i = 0; i < nsd->child_count; ++i) {
nsd->children[i].need_to_send_STATS = 1;
nsd->children[i].handler->event_types |= NETIO_EVENT_WRITE;
}
}
#endif /* BIND8_STATS */
static void
configure_handler_event_types(short event_types)
{
size_t i;
for (i = 0; i < tcp_accept_handler_count; ++i) {
struct event* handler = &tcp_accept_handlers[i].event;
if(event_types) {
/* reassign */
int fd = handler->ev_fd;
struct event_base* base = handler->ev_base;
if(tcp_accept_handlers[i].event_added)
event_del(handler);
event_set(handler, fd, event_types,
handle_tcp_accept, &tcp_accept_handlers[i]);
if(event_base_set(base, handler) != 0)
log_msg(LOG_ERR, "conhand: cannot event_base");
if(event_add(handler, NULL) != 0)
log_msg(LOG_ERR, "conhand: cannot event_add");
tcp_accept_handlers[i].event_added = 1;
} else {
/* remove */
if(tcp_accept_handlers[i].event_added) {
event_del(handler);
tcp_accept_handlers[i].event_added = 0;
}
}
}
}
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